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i
HYDROLOGIC KNOWLEDGE IN ANCIENT INDIA
[Second Edition]
National Institute of Hydrology (Ministry of Water Resources, River Development and Ganga Rejuvenation)
Jal Vigyan Bhawan
Roorkee-247 667 (Uttarakhand), India
December, 2018
ii
Shlokas for Invoking River Goddess
गग च यमन चव गोदावरि सिसवति ।
नममद तसध कावरि जलऽसमिन सतितध कर ।। Sri Bruhannardiya Puran
Meaning: O rivers Ganga, Yamuna, Godavari, Saraswati, Narmada, Sindhu and Kaveri,
please enrich the water I am bathing with, with your presence.
गगा तसध सिसवति च यमना गोदावरि नममदा ।
कावरि शिय महनदरिनया चममणविी वतदका ।।
तिपरा वतरविी महासिनदी खयािा जया गणडकी ।
पराम: परमजल: समदरसतहिा: कवमनत म मगलम ।।
Meaning: May rivers Ganga, Sindhu, Saraswati, Yamuna, Godavari, Narmada, Kaveri,
Sharyu, Mahendratanaya, Chambala, Vedika, Kshipra, Vetravati (a rivulet), chiefly the
Mahasurnadi, Jaya and Gandaki become sacred and absolute, and along with the sea,
shower benevolence on me.
नमातम गग िव पादपकज सिासिवमसमिितदवयरपाम ।
भसमत च मसमत च ददातस तनतय भावानसािर सदा निाराम ।
Meaning: O Mother Ganga, the bestower of all worldly happiness, pleasures and Moksha
as per the different levels of bhav of the worshipper, all Deities and demons worship your
Holy feet, I too offer obeisance at your Holy feet.
iii
Preface to the Second Edition
For human beings, water is not merely a substance that sustains life. Water management is an
elemental ingredient in the way people conceive the world and an expression of their thoughts
and emotions. Hydrologic knowledge in India has a historical footprint of several millenniums.
As in many ancient civilisations across the world, the need to manage and use water drove the
growth of hydrology in ancient India also. Evidences from ancient history provide an insight into
the hydrological knowledge generated by Indians more than 5000 years ago. What is less known,
however, is the rigorous discussion on several aspects of hydrologic processes in the ancient
Indian scriptures as we understand them today.
This report reveals that the knowledge of hydrology was pervasive in ancient India starting from
pre- Indus Valley Civilization days and has been discussed in-depth in Vedas, Puranas,
Arthasastra, Astadhyayi, Vrhat Samhita, Ramayana, Mahabharat, Meghmala, Mayurchitraka,
Jain and Buddhist and many other ancient literatures. However, it had remained unearthed and
unexplored in front of the world at large till the recent times. This report, like its predecessor, is
a sincere effort to present the ancient Indian hydrologic knowledge to the Indian and the world
community. The report has a special importance, particularly in an era of population growth,
environmental degradation and climate change leading to increasing hydrological extremes and
stresses. The climate change phenomenon would also have greater impacts on water and food
security. At the same time, the competition among various water sectors is increasing and thus
requiring a larger emphasis on water resources management to achieve the goals of sustainable
development (SDGs). The ancient water technologies discussed in this book should be
considered not merely as historical artefacts, but as potential tools for sustainable water
technologies for the present and the future.
While updating the report, a number of recent national as well as international research papers
and technical book published by various national and international institutions have been
referred. Figures illustrating various concepts, hydrological processes and water engineering
techniques have also been included to clarify the concepts and help forming clear mental image
of the developments. While revising, the title of the report has been slightly changed from
“Hydrology in Ancient India” to “Hydrologic Knowledge in Ancient India”. I compliment the
authors of the first edition of the report for their vision and efforts. I thank Dr. Suhas Khobragade,
Scientist-F; Dr. P. K. Singh, Scientist-D; Dr. A. K. Lohani, Scientist-G; Md. Furqan Ullah,
ALIO; and Mrs. Charu Pandey, LIA for their sincere efforts to update the report. In this report,
material from various sources has been compiled. The sources and their contributors are duly
and thankfully acknowledged.
A softcopy of the report and more information about the institute is available at
www.nihroorkee.gov.in.
Roorkee, Dec. 01, 2018
iv
v
Preface to the First Edition
vi
vii
CONTENTS
Title Page No.
Preface to the Second Edition iii
Preface to the First Edition v
List of Figures ix
List of Tables ix
List of Abbreviations xi
Summary xiii
Chaper 1: Introduction 01
Chaper 2: Hydrologic Cycle 13
Chaper 3: Cloud Formation, Precipitation, and its Measurement 25
Chaper 4: Interception, Infiltration and Evapotranspiration 53
Chaper 5: Geomorphology and Surface Water 63
Chaper 6: Ground Water 69
Chaper 7: Water Quality and Waste Water Management 79
Chaper 8: Water Resources Utilization, Conservation and Management 91
Chaper 9: Concluding Remarks 99
Bibliography 101
Glossary of Terms 107
viii
ix
LIST OF FIGURES
Fig. No. Title Page No.
1.1 The Great Bath of Mohenjo-Daro 05
1.2 Sophisticated Water Reservoir at Dholavira, evidence for hydraulic
sewage systems in the ancient Indus Valley Civilization 06
2.1 Representation of the various processes of the hydrologic cycle 13
2.2 Schematic Representation of the Hydrological Cycle extracted from
Kishkindha Kanda of Ramayana of Valmiki by Malik (2016) 22
2.3 Schematic comparisons between Modern Hydrological cycle and
hydrological cycle concept in Valmiki Ramayana by Malik (2016) 22
3.1 The process of Cloud Formation 26
3.2 The Symon’s raingauge (Modern raingauge) 49
6.1 Wells discovered at Lothal, 2600 BC 69
6.2: Unconfined aquifer showing different zones 71
7.1 Drainage and sanitation systems of Mohenjo-Daro and Lothal
cities of Indus valley civilization 89
8.1 Ahar Pyne system in Gaya, South Bihar 94
8.2 A view of Sudarsana lake Girnar, Junagadh, Gujarat 95
LIST OF TABLES
Table No. Title Page No.
1.1 Some selected shlokas (prayers) invoking water as God 07
x
xi
LIST OF ABBREVIATIONS
(with approximate date of works)
A.V. Atharva Veda (Latest Veda, Before 800 B.C.)
BP Bhava Prakash (16th Century A.D.)
Brahmand Brahmanda Purana (3rd – 4th century A.D.)
Garuna Garuna Purana (6th Century B.C.-7th Century A.D)
GB Gopatha Brahmana (around 1000 B.C.)
Kurma Kurma Purana (600 B.C. to 700 A.D.)
Linga Linga Purana (600 B.C. to 700 A.D.)
M.B. Mahabharata (400 B.C. to 400 A.D.)
Markandeya Markandeya Purana (6th Century B.C. to 4th Century A.D.)
Matsya Matsya Purana (6th Century B.C. to 4th Century A.D.)
Narada Narada Purana (600 B.C. to 275 A.D.)
Padma Padma Purana (600 B.C.-400 A.D.)
Rama. Ramayana (800 B.C.-200 B.C.)
R.V. Rig Veda (3000 B.C. or before)
S.V. Sam Veda (3000 B.C.)
SB Satpatha brahmana (2000 B.C.)
Skanda Skanda Purana (7th century A.D.)
Tai. Ara. Taithiriya Aranyaka
T.S. Taithiriya Samhita (later than Rig Veda, 1500 B.C.-800
B.C.)
Vais. Sutr. Vaisesika Sutra (600 B.C.-700 B.C.)
Vayu Vayu Purana (200 B.C.-400 A.D.)
Vishnu Vishnu Purana (600 B.C.-275 A.D.)
Y.V. Yajurveda (later than Rig Veda, 1500 B.C.-800 B.C.)
xii
xiii
Our existence is dependent on water in many ways. Infact, one could say that our whole
civilization is built on the use of water. India is a country with more than five thousand years of
civilization, with great contributions to the field of hydrology. Ancient Indian civilization,
referred to as Indus Valley Civilization or Harappan Civilization was at its prime around 3300–
1300 BC. It is now known that Harappan people had sophisticated systems of water supply and
sewerage, including hydraulic structures such as dams, tanks, lined wells, water pipes and flush
toilets. The cities of Harappa and Mohenjo-Daro developed the world's first urban sanitation
system. Large scale agriculture was practiced and an extensive network of canals was used for
the purpose of irrigation in Indus valley civilization. Sophisticated storage systems were
developed including the reservoir built at Girnar in ca. 3000 BC.
The ancient Vedas, Puranas, Meghmala, Mayurchitraka, VrahtSamhita, literature of Buddhism
and Jainism and various other works are enriched with plethora of knowledge about natural
systems, including earth, atmosphere, hydrosphere, lithosphere and their interaction with the
human beings. If one studies these ancient Sanskrit literature, (s)he observes that it contains
valuable references to hydrology. It is observed that in ancient India, the information on various
hydrological processes was very well known. Evaporation, condensation, cloud formation,
precipitation and its forecasting were well understood in ancient India. Raingauges were
developed and were widely used during the Mauryan period (4th cent. B.C.) to measure rainfall
and its seasonal variation, based on the same principles as that of modern hydrology. While the
western knowledge about the occurrence of ground water was based on wild theories, the Indians
had well-developed concepts of ground water occurrence, distribution and utilization. Literature
also reveals that hydrologic indicators were used to detect the presence of ground water. Well
organized water pricing system was also in place during Mauryan era. Various references are
available in Vedas alluding the importance of efficient water use so as to reduce the intensity of
water scarcity and drought etc.
In the present report, an attempt has been made to compile knowledge and wisdom pertaining to
hydrology in ancient Indian literature. At this juncture, it is high time that we recognize and
appreciate our traditional wisdom and practices and blend them appropriately with our current
systems of water management. Such overdue initiative will definitely create a synergy of the
OLD and the NEW.
SUMMARY
xiv
1
Science improves our knowledge of the nature and living beings. It helps the humans to
investigate the several unknowns of the universe and generates solutions for practical problems.
In fact, science has several functions, including the attempt to improve the quality of the human
life. In ancient days, although science was unknown as such, yet man had realized the importance
of water for survival, and therefore, the earliest civilizations were distinctly and predominantly
hydraulic in character as they owed their origin to reliable sources of water to meet their various
needs. Rivers played such a pivotal role in the life and living of those people that their
civilizations came to be known as river valley civilizations. Prominent among these were the
Nile valley civilization in Egypt, the Tigris valley civilizations in Mesopotamia, the Howang-Ho
valley civilization in China and the Indus valley civilization in India. Most of these civilizations
existed from 3500 to 300 BC and there are historical evidences to show that certain engineering
measures were adopted by them to sustain as well as enhance benefits from rivers and also to
protect against damages due to floods and droughts.
Humankind established permanent settlements about 10,000 years ago when people adopted an
agrarian way of life. Due to settled and somewhat secured life, population began to expand faster
than ever before. Settled agricultural life made it possible to construct villages, cities and
eventually states, all of which were highly dependent on water (Vuorinen et al., 2007). This
created a unique relationship between humans and water. Most of the ancient civilizations, i.e.,
Indus valley, Egyptian, Mesopotamian and Chinese were developed at places where water
required for agricultural and human needs was readily available, i.e., close to springs, lakes,
rivers and at low sea levels (Yannopoulos et al., 2015). Most ancient civilizations were highly
developed and technologically equipped for societal sustainability as well as to enhance benefits
from rivers and also to protect against damaging floods and other hydrological extremes. Water
transport over long distances was based on gravity. Thus, long aqueduct systems (indeed,
sometimes exceeding 100 km) were used to convey water over large distances, using gravity.
Also, water cisterns for harvesting rainwater, canals and ground water wells were practiced since
the Bronze Age (ca. 3200–1100 BC). However, fall of these civilizations and gradual decay of
some of them were partly prompted by mankind’s creeping inability to cope up with adverse and
Chapter-1
INTRODUCTION
2
damaging consequences of his interference with hydrology and hydraulics of the respective
rivers in his attempts to derive benefits. Scarborough et al. (2003) and Ortloff et al. (2009) have
reviewed how water management affected ancient social structures and organization through
typical examples in the Eastern and Western hemispheres, covering the whole ancient world.
It is well known that in the realm of spiritual values, the Indian heritage has been great and
sublime and perhaps unparalleled, as testified by some of the great personalities of the west who
underwent the toil of learning Sanskrit and presenting the world with translation of the renowned
texts of Vedas and Upanishads in English and German. Besides the spiritual growth, ancient
India also exhibited the growth of science. The Indus Valley civilization, one of the earliest and
most developed civilizations of that time, was the world's largest in extent and epitomises the
level of development of science and societies in proto-historic Indian sub-continent. Ancient
Indian literature, dating back from the age of the Vedas, further witnesses this development of
sciences (including the water science). It is a good fortune that the ancient Indian Sanskrit works
have been preserved and not lost through centuries of domination by alien races and alien
cultures in India.
Science in Ancient India
Very few workers in the scientific world are aware of how much science, as understood and
accepted by scientists, is contained in the ancient Sanskrit literature. It is a moot question whether
the ancient sages had adopted the methods of modern science of laboriously collecting
observational data and integrating them through appropriate concepts into useful and acceptable
truths. Observation as a medium of realizing the underlying truths could not have been ignored.
Science is defined as ordered knowledge of natural phenomena and the rational study of the
relations between the concepts in which these phenomena are expressed. It is in its widest sense,
“a systematic method of describing and controlling the material world”. It can be seen, as it
stands at any moment, as a logical and coherent account of that order which the scientists of the
time find in nature. It progressively affects man’s life.
In India, at the beginning of the third/fourth millennium B.C., a highly developed civilization,
popularly known as the Indus Valley civilization or Harappan Civilization (a Bronze Age
civilization) grew in parts of Pakistan and northwest India, on the fertile plains of the Indus River.
The Harappan civilization was mainly located in present-day Indian states of Gujarat, Haryana,
3
Punjab, Rajasthan, Uttar Pradesh, Jammu and Kashmir; and present-day Pakistan provinces of
Sindh, Punjab, and Balochistan. It was located mainly in the region of the Indus and Ghaggar-
Hakra Rivers. The major urban centres were at Harappa, Mohenjo-daro, Dholavira, Ganeriwala
and Rakhigarhi.
The people of the Indus Civilization made great scientific advancements. They achieved great
accuracy in measuring length, mass, and time. These people were among the first to develop a
system of uniform weights and measures. Preparation of the Vedic calendar for various
ceremonies and of rituals necessitated the study of heavenly bodies and of their movements. This
led to the advancement of the astronomical Science (Prasad, 1980). The fact that sun light
constitutes seven colour rays was known to Vedic Aryans, as evident from the following shloka
of the Rig Veda (RV.II,12.12),
;%lIrjf”eo`Z’kHkLrqfo’ekuokl`tRlrZoslIrflU/kwuA
;ksjksfg.keLQqj}tzokgq?kkZekjksgUra l tuklbUnz%A (RV.II,12.12)
Meaning: the sun containing seven colour rays is the cause of water flow in the rivers (because
of rain). After rain, it again attracts water from earth and this cycle goes on.
Indian arithmetic is remarkable in that there is evidence to show that as early as third century
B.C., a system of notation was evolved from which the scheme of numerals that is in vogue even
today has been copied. The Aryabhatta (476–550 CE), a great mathematician and astronomer,
studied the summation of arithmetic series and attempted to solve quadratic indeterminate
equations. Brahmagupta, the great mathematician of 7th century, developed application of
explicitly general algebraic methods to astronomical problems. The beginning of the medical
sciences goes back to the age of the Vedas. The early beginnings of the art of healing and of the
knowledge of healing herbs are found in the ‘Kausikasutra’ of the ‘Atharvaveda’. Susruta and
Charaka were well known surgeons and physicians. During the Buddhist period, renowned
scholar Jivaka was famous for his amazing medical and surgical cures. Medicine was also an
important and compulsory subject in the ancient universities of Taksasila, Nalanda and
Vikramasila. The medical work of Vagbhata of the seventh century contains the first mention of
mercury (Prasad, 1980). The most remarkable feature of the Buddhist Philosophy of India is the
formulation of the atomic theory by Kanada (600 B.C.) (Prakash, 1965). Biswas (1969) has
rightly remarked that the growth of modern science in Europe would have been hardly possible
4
without the background of pioneering contributions from India, China and Arabian countries,
well up to the 12th century A.D.
Domination of the foreign rulers for a long time did not help in bringing the scientific content of
the Sanskrit and other literature to come to the fore. Even after independence, the situation did
not improve for the obvious reason that there is no interaction between the modern scientists and
the Sanskrit scholars. The scientist never bothered to know about the scientific content in the
ancient Sanskrit literature while the Sanskrit scholars never cared to bring to focus the problems
of scientific nature available in the Sanskrit works. They got entangled themselves in problems
such as ‘Vyakarana’, Mimansa’ etc. Hence, even to date, the scientific contents of the ancient
works have remained almost wholly unknown and unanalyzed.
Significance of Water in Indian Traditions
Since ancient times India is known as the land of culture and spiritualism. Water has always had
a pervasive influence on the cultural and the religious life of Indian people. The Great Bath of
Mohenjo-Daro is a great testimony to this fact (Fig. 1.1). The bath is considered by scholars as
the "earliest public water tank of the ancient world". Although, the exact significance of the
structure is unknown, most scholars agree that this tank was used for special religious functions.
5
Fig. 1.1: The Great Bath of Mohenjo-Daro (Source: Wikipedia)
Drier climates and water scarcity in India led to numerous innovations in water management.
Since Indus valley civilization. Irrigation systems, different types of wells, water storage systems
and low cost and sustainable water harvesting techniques were developed throughout the region.
The reservoir built in 3000 BC at Girnar and the ancient step-wells in Western India are examples
of some of the skills. Technologies based on water were also prevalent in ancient India.
Reference to the manually operated cooling device “Variyantra” (revolving water spray for
cooling the air) is given in the centuries old writing “Arthashastra” of Kautilya (400 BC). The
“Arthashastra” and “Astadhyayi” of Panini (700 BC) give reference to rain gauges (Nair, 2004).
6
Fig. 1.2: Sophisticated Water Reservoir at Dholavira, evidence for hydraulic sewage systems in
the ancient Indus Valley Civilization (Source: Wikipedia).
In the Vedic and other Indian traditions, all natural forces including planets and rivers are
personified as gods and goddess and worshipped. Early Indian culture originated near river
regions. As a matter of fact, the very name of the country is derived from the name of river Indus.
The seven rivers namely Ganga, Yamuna, Saraswati, Narmada, Godavari, Krishna and Kaveri
are considered important on cultural basis. For example, the Holy River Ganges is
mythologically linked to Lord Shiva and is considered by the Hindus as the symbol for
purification of the soul and rejuvenation of the mind. All over India people throng for a dip in
the holy river to wash away their sins. Divine water is consumed in the temple after puja worship
rituals; idols of worship are sprinkled with water (abhishekam); and a plantain leaf kept for a
meal is cleaned with water and a prayer. Table 1.1 presents some of the important shlokas in the
Sanskrit which are invoked while offering prayers to water as God.
7
Table 1.1: Some selected shlokas (prayers) invoking water as God
SHLOKA MEANING
आपो तहषठा मयोभवसथा न ऊज दधािन ।
मह िराथ चिस ॥१॥
ह जल ! आपकी उपसमसथति स वायमडल बहि ििोिाजा ह, औि
हम उतसाह औि शसमत परदान कििा ह। आपका शदध साि हम
परसि कििा ह, इसक तलए हम आपको आदि दि ह |
O Water, because of your presence, the atmosphere is
so refreshing, and imparts us with vigour and
strength. We revere you who gladdens us by
your pure essence.
यो वः तशविमो िससतसय भाजयिह नः ।
उशिीरिव माििः ॥२॥
ह जल ! आप अपना यह शभ साि, कपया हमाि साथ साझा
कि , तजसपरकाि एक मा की इचछा होिी ह की वह अपन बचो
को सवमशरषठिम परदान कि |
O Water, this auspicious sap of yours,
please share with us, like a mother desiring (to share
her best possession with her children).
ििा अि गमाम वो यसय ियाय
तजनवथ ।
आपो जनयथा च नः ॥३॥
ह जल ! जब आपका उतसाही साि तकसी दखी परारी को परापत
होिा ह, िो वह उस जीवि कि दिा ह | हजल !
इसतलएआपहमािजीवनदािाह।
O Water, when your invigorating essence goes to one
affected by weakness, it enlivens him,
O Water, you are the source of our lives.
श नो दवीितभषटय आपो भवनत पीिय ।
श योितभ सरवनत नः ॥४॥
ह जल ! जब हम आपका सवन किि ह िो उसम शभ तदवयिा
होन की कामना किि ह | जो शभकामनाए आपम तवदयमान ह ,
उसकाहमाि अदि सचिर हो।
O Water, may the auspicious divinity which
is wished for, be present in you when
we drink (water). May the auspiciousness which
supports you, flow to us.
ईशाना वायामरा ियनतीशचरमरीनाम ।
अपो याचातम भरजम ॥५॥
ह जल ! हो सचरिि भी म भतमयो कतर तदवयिा आपकी ह जल,
मिा आगरह ह तक आप फसलो का समतचि पोरर कि ।
O Water, may the divinity in Water dwell in
the farm lands. O Water, I implore you to
give nutrition (to the crops).
8
अपस म सोमो अबरवीदनततवमशवातन भरजा ।
अति च तवशवशभवम ॥६॥
ह जल , सोमा न मझ बिाया तक जल म दतनया की सभी
औरधीय जडी बटीया औि अति जो दतनया को सख समसमदधपरदान
कििी ह भी मौजद ह।
O Water, soma told me that in water is present
all medicinal herbs of the world, and also agni (fire)
who brings auspiciousness to the world.
आपः परीि भरज वरथ िनवऽ मम ।
जयोकच सय दश ॥७॥
ह जल, आपम औरधीय जडी बतटया परचि मातरा म समायी हई ह;
कपया मि शिीि की ििा कि , िातकमसयमकोलबसमयिकदखसक
(अथामिमलबसमयिकजीतवििहसक|
O Water, you are abundantly filled with Medicinal
Herbs; Please protect my body, so that I
can see the sun for long (i.e. I live long).
इदमापः पर वहि यसमक च दरिि मतय ।
यदवाहमतभददरोह यदवा शप उिानिम ॥८॥
ह जल, मझम जो भी दषट परवतियो ह, कपया उनहदि कि, औि
मि मसमसतषक म तवदयमान समसत तवकािो को दि कि औि मि
अिममन म जो भी बिाइया ह उनह दि कि ।
O water, please wash away whatever
wicked tendencies are in me, and also wash away
the treacheries burning me from within, and
any falsehood present in my mind.
आपो अदयानवचारिर िसन समगितह ।
पयसवानि आ गतह ि मा स सज वचमसा ॥९॥
ह जल, आप जो उतसाही साि स भि हए ह, म आपकी शिर
मआया ह | म आप म गहिाई स सममातहि ह (कि सनान अथामि )
स तििा हआ ह )अति तसदधाि( जो अति; मझम चमक पदा कि।
O Water, today, to you who is pervaded by fine
rasa (invigorating sap) I came, I deeply enter (i.e.
bathe) in you who is pervaded by agni (fire principle);
may that agni produce lustre in me.
Hydrologic Knowledge in Ancient India
The historical development of hydro-science has been dealt by many writers (Baker and Horton,
1936; Chow, 1964; Biswas, 1970); but in all these works references to the contributions made in
ancient India is conspicuously absent (Prasad, 1980). Chow (1964), for example, describing the
history of hydrology, has referred to the works of Homer, Thales, Plato, Aristotle in Greece,
Pliny in Rome and many Biblical scholars of that time but has not made any reference to any
9
Indian scholars and literature, and their great contributions. Most of these western scholars
believed in the wild theories regarding origin of water. Thales, an Ionion philosopher,
mathematician and astronomer for example, stated that the sea water driven into rocks by wind
is the cause of ground water. Plato (427-347 B.C.), the great Athenian philosopher, stated that
the water of seas, rivers, springs etc. come from a large underground reservoir and goes back to
the same. Aristotle (384-322 B.C.) said that water of the springs etc. is derived from the
underground water through system of underground openings. Famous Stoic philosopher Lucius
Annacus Sencca (4 B.C.) declared that rainfall cannot be the source of springs and underground
water, because it penetrates only a few feet into the earth (Prasad, 1980). Marcus Vitruvious who
lived about the time of Christ conceived a theory saying that ground water is part of rainfall
originated through infiltration. All these theories of the western scholars indicate a low level of
development of hydroscience in the western world during ancient times. On the other hand,
contemporary Indian scholars appear to have developed an advanced level of knowledge about
the various aspects of water science, as reflected in the ancient Indian literature which contains
very valuable and important scientific discourses on hydrology and their practical applications.
There are adequate archaeological evidences to testify that the Harappans of the Indus Valley
were well aware of the seasonal rainfall and flooding of the river Indus during the period between
2500 and 1700 B.C., which is corroborated by modern meteorological investigations (Srinivasan,
1975). The Vedic texts, which were composed probably between 1500 and 1200 BC (1700–
1100 BC according to some scholars), contain valuable references to ‘hydrological cycle’. The
important concepts of hydrology are scattered in the Vedas in various verses, in the form of
hymns and prayers addressed to various deities. Likewise, other Sanskrit literature also contains
valuable knowledge related to the science of hydrology.
The origin and evolution of agriculture and experience in irrigation on the territory of India or
anywhere in the world are not separate processes, as evidenced from following hymns of the
Yajur Veda:
d`f’k”pesa ;Ksudy~iarkeA
o`’V”pesa ;Ksudy~iarkeAA ;tqosZn] 18&9AA
ek:r”pesa ;Ksudy~iarkeAA ;tqosZn] 18&17AA
These hymns illustrate the importance of Yajna’s (;K( Sacrifice) for rain, agriculture, and air or
environment and their interrelationship.
10
That water is not lost in the various processes of the hydrological cycle namely evaporation,
condensation, rainfall, streamflow etc., but gets converted from one form to other was known
during Vedic and later times. Water uptake by plants, division of water into minute particles by
sun rays and wind, different types of clouds, their heights, their rainfall capacities etc. along with
the prediction of rainfall quantity in advance by means of observing the natural phenomena of
previous years are also available in Puranas, Vrhat Samhita (550 A.D.), Meghamala (900 A.D.)
and in other literature. The references to rain gauges are available in Arthasastra of Kautilya (400
B.C.), and Astadhyayi of Panini (700 B.C.). The quantity of rainfall in various parts of India was
also predicated by Kautilya. Indians were acquainted with cyclonic, orographic effects on rainfall
and radiation, and convectional heating of earth and evapotranspiration. Various other aspects
such as infiltration, interception, stream flow and geomorphology, erosive action of rainfall, etc.
were also known. In Ramayana (200 B.C.) the reference to artesian wells is available. Ground
water development and water quality consideration were also getting sufficient attention in
ancient India is evident from the Vrhat Samhita (550 A.D.).
References to water management and conservation, well organized water pricing system around
400 B.C., construction methods and materials of dam, tanks etc., bank protection, spillways etc.
in the ancient Sanskrit literature reflect the high stage of development of water resources and
hydrology in ancient India. Numerous references exist in Vedic literature, Arthashastra, Puranic
sources, VrhatSanhita, Mayuracitraka, Meghmala, Jain, Buddhist and other ancient Indian
literature which illustrate the status of hydrology and water resources in ancient India. The
various elements of hydrology and water resources as they are discussed in an inferred from the
various ancient Indian literature and also discussed by some of the authors such a Tripathi (1969),
Prasad (1980), Prasad (1987), and others have been reviewed, analyzed and presented in this
volume.
The various aspects of knowledge hydrology and water resources in ancient India have been
discussed and presented in this report under the following chapters:
1. Introduction
2. Hydrologic Cycle
3. Cloud Formation, Precipitation, and its Measurement
4. Interception, Infiltration and Evapotranspiration,
5. Geomorphology and Surface Water
11
6. Ground Water
7. Water Quality and Waste Water Management
8. Water Resources Utilization, Conservation and Management
9. Concluding Remarks
12
13
Hydrologic Cycle is a fundamental and important concept in hydroscience. The cycle involves
the total earth system comprising the atmosphere (the gaseous envelop), the hydrosphere (surface
and subsurface water), lithosphere (soils and rocks), the biosphere (plants and animals), and the
Oceans. Water passes through these five spheres of the earth system, in one or more of the three
phases: solid (ice), liquid and vapour. Figure 2.1 represents the various processes of the
hydrologic cycle.
Figure 2.1: Representation of the various processes of the hydrologic cycle
(Source: John Evans and Howard Periman, USGS - http://ga.water.usgs.gov/edu/watercycle.html)
The Vedic texts which are more than 3000 years old contain valuable references to water and the
‘hydrologic cycle’. As mentioned earlier, the most important concepts, on which the modern
science of Hydrology is founded, are mentioned in Rig Veda in various verses in the form of
hymns and prayers addressed to various deities and divinities such as Indra (firmament), Agni
(fire), Maruts (wind) and so on. For example, a verse from Rig Veda states like this:
Chapter-2
HYDROLOGIC CYCLE
14
vkng Lok/kkeuq iquxZHkZRoesfjjsZA
n/kkukuke% ;fK;eAA R.V., I,6.4 AA
It means that the water which gets divided in minute particles due to the heat of sun is carried by
wind and after the conversion into cloud it rains again and again. Another verse of the Rig Veda
(R.V, I,7.3) states that the God has created sun and placed it so, that the whole universe gets
illuminated, likewise this is the rule of universe to extracts up water continuously and then
convert it to cloud and ultimately discharge as rain.
bUnzks nh?kkZ; p{kl vk lw;Z jksº;kfnn~frA
fo xksfHkjkfnzeSj;rAA R.V. I,7.3 II
Following verses of Rig Veda explain the transfer of water from earth to the atmosphere by the
wind (I, 19.7), breaking up of water into small particles and evaporation due to sun rays and
subsequent rain (I, 23.17), the formation of cloud due to the water evaporated from the mother
earth and its come back to its mother in the form of rain (I,32.9).
The verse I,32.10 of the Rig Veda says that the water is never stationery. It continuously gets
evaporated and comes down, but due to smallness, we can’t see the rising water particles.
; bZ[M+;Ur ioZerku~ frj% leqnze.kZoe~A
e:n~fHkjXu vk xfgAAR.V., I,19.7 II
vew;kZ mi lw;sZ ;kfHkokZ lw;Z% lgA
rk uks fgUoURo?oje~AAR.V., I,23.17 AA
uhokr;ka vHkon~o`=iqRrsUnzks vL;k vo v/ktZHkkjA
mRRjk% lwj/kj% iq= vklhnnuq% “k;s lgoRlku/ksuq%AA R.V., I,32.9 AA
The following verses of the Rig Veda say that the rays of the Sun are the cause of rains and that
the sun extracts water from all parts of the world and the start of creation is through fire only,
which is continuously engaged in extraction and discharge of water.
vfr’BUrhuke foos”kukuka dk’Bkuka e/;s fufgraaa “kjhje~A
c`=L; fu.;a fo pjUR;kiks nh?kZre~ vk”k;fnUnz”k=q%AAR.V., I,32.10 AA
15
_ra nsok; dIors lfo= bUnzk;kfg?ks u jeUr vki%A
vºjº;kZR;Drqjika fd;kR;k izFke% lxZ vklke~AAR.V., II,30.1 AA
;ks o`=k; flue=kHkfj’;Riz ra t fu=h fonq’k mokcA
iFkks jnUrhjuq tks’keLeS fnosfnos /kuq;ks ;UR;FkZe~AAR.V., II,30.2 AA
A verse of Rig Veda further states as follows:
;k vkiks fnR;k mr ok L=oUr [kfuf=ek mr ok ;k% LO;atk%A
leqnzk;kZ ;k% “kqpo% ikodkLrk vkiks nsohfjg ekeoUrqAAR.V., VII,42.2 II
Meaning: The waters which are from heaven, of those which spring up by themselves, the bright
pure waters that tend to the sea, may those divine waters protect me here. Like these verses,
various other verses of the Rig Veda (RV. VIII,6.19, VIII,6.20; and VIII, 12.3) states the
causation of water evaporation, formation of cloud, rain, flow of water and its storage in oceans
etc.
The verse RV. X,27.33 of Rig Veda reads as follows:
nsokuka ekus izFkaek vfr’BkUd`Ur=kns’kkeqijk mnk;u~A
=;LrifUr i`fFkoheuw’kk }k ccwda ogr% iqjh’keAAR.V., X,27.23 AA
Meaning: At the start of creation, sun, etc. are created, rainfall is caused from sky and the
vegetation is created by the combination of cloud, air and sun. The sun extracts water in the form
of vapour & air, causes it to form cloud and rain.
Further elaboration of the knowledge about hydrologic cycle is found in the Sam Veda (VI-607).
A verse of Sam Veda reads as follows:
leU;k ;UR;qi;UR;U;k% lekuewoZ u?kLi`.kkfUrA
re~ “kqfpa “kqp;ks nhfnokaleikUuikreq; ;UR;k;%AAS.V. iwokZfpd VI, 607 AA
16
Meaning: One type of water goes up and other type of water comes down, both of these may go
to the atmosphere after treatment of sun’s heat. From up they flow into rivers after rain and get
stored there.
Similarly, the Yajur Veda explains the process of water movement from clouds to earth and its
flow through channels and storage into oceans and further evaporation (Y.V., X-19).
iz ioZrL; o`’kHk’; i`’.kUuko”pjkfUr LoflpK;kuk%A
rk vkoo=Uu/kjk xqnDrk vfga cqgU;euq jh;ek.kk%
fo’.kksfoZØe.kefl fo’.kksfoZØkUrefl fo’.kksZ% ØkUreflAAY.V., X-19 AA
In the Rig Veda, Sam Veda and Yajur Veda the concept of infiltration, water movement, storage
and evaporation as the part of hydrologic cycle are revealed clearly. During the time of Atharva
Veda the concept of water evaporation, condensation, rainfall, river flow and storage and again
repetition of cycle was explained as in the earlier Vedas. According to the Atharva Veda, the sun
rays are the main cause of rain and evaporation, as mentioned below:
vew;kZ mi lw;sZ ;kfHkxZ lw;Z% lgA
rk uks fgUoURo/ojeAA A.V., I,5.2 AA
The verse I, 32.4 of the Atharva Veda states that the entry of rainwater into earth and its
continuous movement in the cycle from earth to atmosphere is by sun rays. The Verse reads as
below:
fo”oeU;keHkhokj rnU;L;kef/k fJre~A
fnos p fo”oosnls i`fFkO;S pkdja ue%AAA.V.,I,32.4 AA
Another Verse of the Atharva Veda (V,24.5) says that the water from earth goes to the
atmosphere due to oxygen and then it comes down (rains) due to carbon dioxide.
fe=ko#.kkS o`’V;kf/kairh rkS ekDrke~A
vLeu~ czg~ea.;fleu~ deZ.;L;ka iqjks/kk;kaeL;ka izfr’Bk;keL;ka
fpR;keL;kekdwR;keL;kaekf”k’;L;ka nsogwR;ka LokgkAAA.V., V,24.5 AA
17
The hydrologic cycle reaches into the atmosphere and traverses, imparts, the domain of
hydrometeorology. It may be seen in the Varahamihira’s Vrhat Samhita (550 A.D.) in which
three chapters are devoted to hydrometeorology comprising pregnancy of clouds (Chapter 21),
pregnancy of air (Chapter 22), and quantity of rainfall (Chapter 23). Shlokas 1 and 2 of
Dakargalam (Chapter 54 of Vrhat Samhita) which states the importance of science of ground
water exploration, helps man to ascertain the existence of water are as follows:
/ke;Z ;”kL;a p onkHkorksga ndkxZya ;su tyksiyfC/k%A
iqalka ;FkkXMs’kq f”kjkLrFSo f{krkofi izksUurfuulaLFkk
,dsu o.ksZu jlsu pkEHk”P;qra uHkLrks olq/kkfo”ks’kkar~A
ukuk jlRoa cgqo.kZrka p xra ijh{;a f{kfrrqy~;esoAAVr.S., 54.1-2 AA
The water veins beneath the earth are like vein’s in the human body, some higher and some
lower. The water falling from sky assumes various colours and tastes from differences in the
nature of the earth. These shlokas imply that the infiltration of rainwater through the veins into
earth surface is the source of ground water. The epic Mahabharata (XII, 183.15.16) explains that
the water ascends to sky with the help of vfXu (fire) and air and then its humidity get condensed
and causes subsequent rainfall.
vfXu% ioula;qDr% [ka lekf{k’krs tye~A
lksfXuek#rla;ksxkn~ ?kuRoeqii?krsA MB,XII,183.15 AA
rL;kdk”ks fuifrr% LusgLr’Bfr ;ks ij%A
l la?kkrRoekiUuks HkwfeRoeuqxPNfrAA MB,XII,183.16 AA
The verses 184.15-17 of the Mahabharata state that the plants drink water through their roots.
The mechanism of water uptake by plants is explained by the example of water rise through a
pipe. It is said that the water uptake process is facilitated by the conjunction of air.
iknS% lfyyikukPp~ O;k/khuka pkfi n”kZukr~A
O;kf/kizfrfØ;RokPp~ fo?krs jlua nzqesAA MB,XII,184.15 AA
oD=s.kksRiyokysu ;Fkks?oZ tyeknnsr~A
rFkk ioula;qDr% iknS% ficfr ikni%AA MB,XII,184.16 AA
18
In verse XII,362.4 and B of the Mahabharata, it is explained that the air and the sun rays get
dispersed and fall on whole universe together. The Verse further says that the sun rains in rainy
season (four months) and in next eight months the same water is again extracted by the sun rays.
Thus, it explains two faces of hydrological cycle clearly viz.
;rks ok;qfoZfu% l`R; lw;Zj”E;kfJrks egku~AA M.B.XII,362.4 AA
;ks’VeklkaLrq “kqfouk fdj.ksuksf{kr Ik;%A
izR;knRrs iqu% dkys fek”p;Zer% ije~%AA M.B.,XII,362.B AA
Like Vedas and Epics, in Puranas (which are dated between 6th century B.C. to 7th century A.D.)
we get various references which show the development of knowledge of hydroscience during
their periods. Matsya Purana (Vo. I, Chapter 54) reveals that the air saturated with moisture is
the cause of creation (earth) viz.
ok;~ok/kkjk oºUrs oS lke`rk% dy~ilk/kdk%AA Matsya I,54.15 AA
In verses I,54.29-34 of the Matsya Purana and 51.23-24-25-26of the Vayu Purana, we come
across the knowledge of evaporation. According to these verses, burning of water and its
conversion to smoke is caused by sun rays which ascend to the atmosphere with the help of air,
which again rains in next 6 months for the goodness of the living beings. The various verses are
given below:
/kzqos.kkf/k’Vrk”pki% lw;ksZ oS x`º~; fr’Bfr
loZHkwr”kjhjs’kq Rokiks g~;kuq”prkf”p;k%AA Matsya I,54.29 AA
nº~;ekus’kq rs’osg tXM+eLFkkojs’kq pA
/kweHkwrkLrq rk º~;kiks fu’ØkeUrhg loZ”k%AA Matsya I,54.30 AA
rsu pkL=kf.k tk;Urs LFkkueHkze;a Le`re~A
rstksfHk% loZyksdsdsHk; vknRrs j”efHktZye~AA I,54.31 AA
leqnzk}k;qla;ksxkr~ oºUR;kiks xHkLr;%A
rrLRo`rqo”kkRdkysifjorZu~ fnokdj%AA I,54.32 AA
19
fu;PNR;kiks es?ksHk;% “kqDyk% “kqDySLrqj”efHk%A
vHkzLFkk% izirUR;kiksok;qukleqnhfjrk%AA I,54.33 AA
rrks o’kZfr ‘k.eklku~ loZHkwrfoo};sA
ok;qfHkLrfurapSo fo/kqrLRofXutk% Le`rkAA Matsya I,54.34 AA
In Linga Purana a full-fledged chapter (I,36) has been devoted to the science of hydrology. It
explains evaporation, condensation and rainfall with suitable examples very scientifically and
says that the water can’t be destroyed, only its state is changed.
nUnº~;ekus’kq pjkpjs’kq xks/kweHkwrkLRoHk fu’ØefUrA
;k ;k Å/oZ ek:rsusfjrk os rkLrkLRoHkka;fXuukok;q pAA Linga I,36.38 AA
vrks /kwekfXuokrkuka la;ksxLRoeqP;rsA
okjhf.k o’kZrhR;HkzeHkzL;s”k% lgL=n`d~AA Linga I,36.39 AA
Meaning: After getting by sun, the water contained in most of the materials on earth gets
converted to smoke (vapour) and ascends to sky with the air and subsequently gets converted to
cloud. Thus, the combination of smoke, fire and air is the cause of cloud formation. These clouds
cause rainfall under the guidance of lord Indra, having thousand eyes.
Similarly verses I,36.66-67 of the Linga Purana say that the water is never destroyed or lost, but
only converted from one form to other i.e. water to vapour by sun heat, then cloud and subsequent
rainfall and loss of rainfall by wind etc. viz.
vL;Sosg izlknkRrq o’VukZrkHkofnnotk%A
lgL= xq.keqRL=’Vaw eknRrs fdj.kStZye~AA Linga I,36.66 AA
tyL; uk”kks o`f}okZa ukrR;sokL; fopkjr%A
/kzos.kkfJ’Brks ok;qof’V lagjrs iqu%AA Linga I,36.67 AA
Thus, it is evident that the Linga Purana contains clear concept of rainfall, evaporation,
condensation, cloud formation etc., along with the knowledge that water cannot be created or
20
destroyed. Chapter 41, Vol. I of the Linga Purana furnishes some more knowledge about the
change in the facets of hydrological cycle with months of the year. viz.
olars pSo xzh’es p “krS% l rirs f=fHk%A
o’kkZaLoFkks “kjfn p prqfHkZL;a izo’kZfrAA Linga I,41.30 AA
pS=s ekfl Hkosna”kq/kkZark oS”kk[krkiuA
ts’Bs ekfl HkosfnUnz vk’kk<+s ok;Zek jfo%AA Ling I,41.33 AA
Likewise Vayu Purana also contains valuable references to hydrologic cycle. Vayu Purana
(51.14-15-16) state like this:
vkfnR;ihra lw;kZXus% lksea laØers tye~A
ukMhfHkokZ;q;qDrkfHkyksZdk/kkua izorZrsAA Vayu,51.14 AA
;RlksekRL=ors lw;Z rnHksz’ofr’BrsA
es?kk ok;qfu?kkrsu fol`tUr tya HkqfoAA Vayu 51.15 AA
,oeqfR{kI;rs pSo irrs pa iqutZye~A
u uk”keq mndL;kfLr rnso ifjorZrsAA Vayu 51.16 AA
Meaning: The water evaporated by sun ascends to atmosphere through the capillary of air, and
there gets cooled and condensed. After formation of clouds, it rains by the force of air. Thus,
water is not lost in all these processes but gets converted from one form to other continuously.
Brahmanda Purana (II, Chapt. 9) also gives some information on the hydrologic cycle. It says
that seven colour rays of the sun extracts water from all sources, by heating them (II,9.138-139).
Thereafter, the clouds of different shapes and colours are formed. Then they rain with high
intensity and great noise. (II,9.167-168). In this way, the fire of the sun is controlled. The very
object of the chapter is the concept of the hydrologic cycle explaining different parts one by one.
uko`’V;k ifjfo”;sr okfj.kk nhI;rs jfo%A
rLekn;% ficU;ks oS nhI;rs jfojacjsAA II,9.138 AA
21
rL; rs j”e;% lIr ficaR;aHkks egk.kZokr~A
rsukgkjs.k lanhIrk%lw;kZa% lIr HkoaR;qrAA Brahmanda II,9.1391 AA
lIr/kk lao`rkRekuLrekfXua “ke;aR;qrA
rrLrs tynk o’kZ eqapafr p egkS?kor~AA II,9.167 AA
lq?kksjef”koa loZ uk”k;afr p ikode~A
izo’VZ”p rFkkR;FkZ okfj.kkiw;Zrs txr~AA Brahmanda II,9.168 AA
The treasure of knowledge about hydrology and hydrologic cycle available in various ancient
Indian literature has still not been explored fully. As observed by V. T. Chow (1974) in the
Symposium organized by UNESCO in Paris in August, 1974 “the history of hydrology in Asia
is fragmentary at best and much insight could be obtained by further study”. Although the efforts
are on, they are not numerous. In a recent study, Malik (2016) has made efforts to extract and
analyze the concept of hydrological cycle as understood from the Ramayana Epic, focusing on
the conceptual aspects of hydrological cycle interpreted from the 28th sarga of 4th Kanda of
Kishkindha Kanda of Ramayana by the great poet Valmiki. The Schematic representation of
hydrological cycle extracted from Kishkindha Kanda of Ramayana of Valmiki by Malik (2016)
is shown in Figure 2.2.
Malik (2016) has also compared the modern concept of the hydrologic cycle with the concept
present during the Ramayana of Valmiki. The comparison is shown in Figure 2.3. From the
comparative analysis of the two concepts, he observes that “in the modern concept sun
throughout the year evaporates the oceanic water or water from others water bodies coupled with
transpiration. But in the epic, there is no signature of transpiration. Also, contrasting difference
occurs for run-off where present concept considering run-off, infiltration and sub-surface flow.
In the epic concept of infiltration and sub-surface flow are found to be lacking”. However, if we
ignore these limitations, the concept of Ramayana is outstanding and very close to the modern
concept.
22
Figure 2.2: Schematic Representation of the Hydrological Cycle extracted from Kishkindha
Kanda of Ramayana of Valmiki by Malik (2016)
Figure 2.3: Schematic comparisons between Modern Hydrological cycle and hydrological
cycle concept in Valmiki Ramayana by Malik (2016)
23
Epilogue
This chapter brings out that the knowledge of water science during the Vedic age and afterwards
in the age of Epics and Puranas was highly advanced, although the people of those times were
solely dependent upon their experience of nature, without sophisticated instruments of modern
times. In the Vedic age, Indians had developed the concept that water gets divided into minute
particles due to the effect of sun rays and wind, which ascends to the atmosphere by the capillary
of air. It gets condensed there and subsequently falls as rainfall. Month-wise change in the facets
of the hydrological cycle was also known. Water uptake by plants which gets facilitated by the
conjunction of air along with the knowledge of infiltration is revealed in the ancient literature.
From all above discourses, we can conclude that well developed concepts of the hydrological
cycle were known to the ancient Indians in those ancient times while the contemporary world
was relying on the wild theories of origin and distribution of water. Thus, the ancient Indian
knowledge of water science can be regarded as the great achievement of that time.
24
25
Precipitation is one of the three main processes (evaporation, condensation, and precipitation)
that constitute the hydrologic cycle, the continual exchange of water between the atmosphere
and Earth’s surface. This chapter discusses various processes such as cloud formation,
interaction between Sun and ocean and earth surface, condensation and precipitation, as
described in the ancient Indian literature. The chapter also sheds lights on the techniques used
for precipitation measurement in ancient India.
Seasons and Clod Formation
The Rig Vedic Aryans had keenly and carefully demarcated the variation in seasons and divided
the whole year into six such divisions as the verse indicates:
mrks l eg~;feUnqfHk% ‘kM~;qDrksZ vuqlsf’k/kr~A
xksfHk;Zoa u pd ` Z’kr~AA R.V., I,23.15 AA
The Sun was clearly known to the Rig Vedic Aryans as determinant of seasons and the seasons
were formed for the benefit of the earthly creatures.
=hf.k tkuk ifj Hkw’kUR;L; leqnz ,da fnR;sdeIlqA
iwokZaeuq iz fn”ka ikfFkZokukerwRizk”kklf} n/kkouq’BqAA R.V., I,95.3 AA
Figure 3.1 shows the general cloud formation and associated processes, as understood in modern
times. The knowledge about cloud formation is also present in the Rig Veda.
Chapter-3
CLOUD FORMATION, PRECIPITATION
AND ITS MEASUREMENT
26
Figure 3.1: The process of Cloud Formation
(Source: https://climate.ncsu.edu/edu/CloudFormation)
Radiation, convection currents and rainfall as their effect, are described in the Rig Veda
(I,164.47, VII, 70.2 and I,161. 11-12) through following verses.
m}RLoLek vd`.kksruk r`.ka fuoRLoi% LoiL;;k uj%A
vxksL;L; ;nlLruk x`gs rn~?kksne`Hkoks ukuq xPNFkAA R.V., I,161.11 AA
laehy~;a ;n~Hkqouk I;ZliZr Do LoRrkR;k firjk o vklrq%A
v”kir ;% djLua o vknns ;% izkcohRizks rLek vcohruAA R.V., I, 161.12 AA
d`’.ka fu;kau gj;% lqi.kkZa viks olkuk fnoeqRirfUrA
r vkoo`=URlnuknrL;kfnn~/krsu i`fFkoh O;q?krsAA R.V., I, 164.47 AA
These above verses of the Rig Veda also state that the rays of the Sun are the cause of the rains,
and that the clouds are constituted of various elements. Some verses of Rig Veda (I,27.6; I,32.8;
I,32.14; I,37.11; II, 24.4; V,55.3) describe the formation of cloud by evaporation of water by Sun
and wind and then rainfall, and there is no other cause of rainfall other than Sun.
foHkDrkfl fp=Hkkuks flU/kks:ekZa vikd vkA
l/kks nk”kq’ks {kjflAA R.V., I, 27.6 AA
27
una u fHkUUeeq;k “k;kua euks :gk.kk vfra ;UR;ki%A
;f”p}=ks efguk I;Zfr’BRrklkefg% iRlqr% “khcZHkwoAA R.V., I,32.8 AA
The above verses explain that all that water goes to the sky with wind by the heat of Sun rays
and gets converted to clouds and then again after the penetration by Sun rays, it rains and gets
stored in rivers, ponds, ocean etc. The clouds are said to be leaders for replenishment of water.
The verse V 55.3 of the Rig Veda explains the simultaneous formation of mighty clouds which
are co-dispensers of moisture.
lkda tkrk% lqHko% lkdeqf{krk% fJ;s fpnk izrja cko/kquZj%
fojksfd.k% lw;ZL;so j”e;% “kqHka ;krkeuq jFkk voRlrAA R.V.,V,55.3 AA
During Rig Vedic times the seasonal variation of rainfall was known, which is depicted through
following verses (RV.VI,20.2 and VI,30.3) saying that the Sun extracts water from Earth during
eight months and then this water rains during rainy season of four months.
fnoks u rqHk;efoUnz l=klq;Za nsosfHk/kkZaf; fo”oe~A
vfga ;Rn`=e;ks ofozokala ºUu`thf’kfUo’.kquk lpku%AA R.V.,VI,20.2 AA
Verse I, 79.2 of the Rig Veda states that the Sun rays strike against moving clouds. Thus, the
black shedders of rain roar. After this, the shower comes with delightful flashes of lighting. The
rains then descend, and finally the clouds thunder.
v rs lqi.kkZa vfHkuUra ,oS% d’.kks uksuko o`’kHkks ;nhne~A
f”kokfHkuZ Le;ekukfHkjkxkRirfUr feg% Lro;UR;HkzkAA R.V.,I,79.2 AA
Following two verses (V.54.2 and V55.5) of the Rig Veda explain the cloud-bearing winds as
the cause of rainfall, viz.
iz oks e#rLrfo’kk mn~U;oks o;kso`/kks v”o;qt% ifjtz;%A
la fo?kqrk n/kfr ok”kkfr f=r% LojUR;kiksbouk ifjtz;%AA R.V.,V,54.2 AA
Meaning: “O cloud-bearing winds, your troops are rich in water, they are strengtheners of life,
and are your strong bonds, they shed water and augment food, and are harnessed with steads
28
(waves) that wander far and spread every-where. Combined with lighting, the triple-group (of
wind, cloud and lightning) roars aloud, and the circumambient waters fall upon the earth”.
mnhj;Fkk e#r% leqnzrks ;w;a o`f’Va o’kZ;Fkk iqjhf’k.ka%A
u oks nL=k mi nL;fUr /kuso% “kqHka ;krkeuq jFkk voRlrAA R.V. V,55.5 AA
This verse explains that the cloud-bearing winds uplift water from ocean and charged with water
shower down the rain. Similarly, instrumentality of winds in the causation of rainfall can be
easily read in verses I,19.3-4; I, 165.1, and their relationship with clouds in I, 19.8 of the Rig
Veda, as follows:
;s egks jtlks fonqfoZ”os nsoklks vnzqg%A e#n~fejXu vk xfgAA
;k mxzk vdZekupqjuk/k’Vkl vkstlk Hk#n~fHkjXu vk xfgAA RV.I,19.3-4 AA
v rs rUoUr jf”efHkfLrj% leqnzekstlkA
e#n~fHkjXu vk xfgAA RV.I,19.8 AA
Both of the above verses reveal the cause of rain, who commands the rain to come down and
execution of eternal laws.
The following hymn (I,38.7) of the Rig Veda reveals how the moisture leaden winds bring some
scanty rainfall in desert region also.
lR;a Ros’kk veoUrks /kUofTonk #fnz;kl%A
fega d`.oUR;okrke~AA R.V.I,38.7 AA
From verse V,53.6-7 of the Rig Veda, we also come across the knowledge of Rig Vedic Aryans
about the positive effect of yajna’s ¼;K½, forests and large reservoirs, causing rainfall.
vk ;a uj% lqnkuoks nnk”kq’ksZ fno% dks”kepqP;oq%A
fo itZU;a l`tfUr jksnlh vuq /kUouk ;fUr o`’V;%AA
rr`nkuk% flU/ko% {kksnlk jt% iz lL=q/ksZuoks ;FkkA
L;Uuk v”ok bok/ouks foekspus fo ;}RrZUr ,U;%AA R.V.V.,53.6-7AA
29
The following hymn from the Rig Veda (V, 53.17) indicates that there are sixty-three types of
winds. However, their climatological and meteorological implications are still unraveled and
they are mostly treated as merely mythologies.
lIr es lIr “kkfdu ,desdk “krk nqn%A
;equk;ef?k Jqreqnzk/kks xR;a e`ts fu jk/kks v”o;a e`tsAA R.V.V,53.17 AA
No clear cut mention of the monsoon is to be found in Rig Veda but the Marut hymns give
satisfactory descriptions. Monsoon is, however, clearly referred to in the later period in the
Yajurveda Samhita as lfyyokr (Taithriya IV.4.12.3).
opZ bna {k= lfyyokreqxze~AA
/k=hZ fn”kka {k=fena nk/kkjksiLFkk”kkuka fe=onLRokst%AA T.S,4.4.12.3 AA
However, a better reference to rain bearing winds is provided in the Rig Veda (R.V. X. 137.2
and I,19.7).
}kfoekS okrkS okr vk flU/kksjk ijkor%A
n{ka rs vU; vk okrq ijkU;ks okrq ;nzi%AA R.V.X,137.2 AA
In versa, VIII,7.4 of the Rig Veda, the word fega is explained to mean mist, with which one cannot
differ easily, if the content is taken into account, though at other places fega signifies rainfall.
oiUr e#rks fega iz osi;fUr ioZrkuA ;|kea ;Ur ok;qfHk%AA R.V.VIII,7.4 AA
The importance of yajna to purify environment and causation of rainfall has also been described
in the Rig Veda (RV.X,98.4; x,98.6/12; x.98.7 and x,98.11) as below:
vk uks nzkIlk e/kqeUrks fo”kkfURoUnz nsº~;kf/kjFka lgL=e~A
fu’khn gks=e`rqFkk ;tLo nsokUnzs ok;s gfo’kk lI;ZAA R.V.X.98.4 AA
vfLeURleqnzs v/;qRrjLeUUiks nsoksfHkfuZo`rk vfr’Bu~A
rk vnzoUukf’Va.ksu l`’Vk nsokfiuk izsf’krk e`f{k.kh’kqAA R.V.X.98.6/12 AA
These hymns clearly describe that the water collected by Sun rays kept in kept in the sky safely,
and to create rain, one should take help of knowledgeable priests, who will do appropriate yajna
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(sacrifice) for rain. This implies that the precipitation is the result of weather and cloud
formation. The three other Vedas, namely Sama, Yajur and Atharva Veda furnish some
additional information on climatology and meteorology which we do not come across in the Rig
Veda. Since these three Vedas chronologically belong to a later period, it can be easily seen that
during the later Vedic period the water science further progressed to a considerable extent.
That the rain is a phenomena of ocean, wind and moisture, is proved to be clearly known by later
Vedic times. Verse from the Tiathriya says “from the Ocean, O Maruts ye make (the rain) to fall,
O Ye that are rich in moisture (TS.II,4.8.2)”.
o`’V;% mnhj;Fkk e#r% leqnzrks nw;a o`f’Va o’kZ;/kk iqjhf’k.k%A
l`tk o`f’Va fno vfnzHk% leqnza i`.kAA TS.II,4.8.2 AA
In Taithriya, it is also very clearly mentioned that the air circulation plays a definite role in the
causation of rainfall. It is stated thus: “Verily becoming of like hue he (wind) causes Parjanya to
rain (TS, II 4.9.I).
ek#rufl e#rkekst bfr d`’.ka okl% d`’.karw’ka ifj /kRr~ ,r}S
o`’V;s #’ka l#i ,o HkwRok itZU;a o’kZ;fr je;r e#r% “;suekf;ufefr Ik”pk}kra
izfr ehofr iqjksokreso tu;fr o’kZL;ko#};S okrekekfu tqgksfr ok;qosZ o`’V;k bZ”ks
ok;qeso Losu Hkkx/ks;suksi /kkofr l ,okLeS itZU;a o’kZ;L; ‘VkSAA TS.II,4.9.1 AA
West wind and the rain bearing monsoon or east wind are spoken of in above lines – “Stay O
Maruts, the speeding falcon (with these words), he pushes back the west wind: verily he produces
the east wind, to win the rains. He makes offering to the names of the wind, the winds rules the
rain (TS.II,4.9.1).
During the Rig Vedic time, probably it was also known to the Aryans that plants (or forests) had
some influence on the causation of rainfall.
lkSHk;;Sokg~R;k fnoks o`’Veo #U/ks e?kq’kk la ;kSR;ika ok ,’k vks’k/khuka jlks
;Ue/oHkn; ,okS’k/khHk;ks o’kZR;Fkks vn~Hk; ,okS’k/khHk;ks of’Va fu u;frAA TS.II,4.9.3 AA
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Like RigVeda, the Yajur Veda also tells about the influence of yajna (sacrifice) in purifying air,
water and environment as a whole, which helps in causation of rainfall. Hymn I,12 of the Yajur
Veda reads as follows:
iko=s LFkks oS’.kO;kS lforqoZ% izlo mRiqukHk;kfPNns.k ifo=s.k lw;ZLFk jf”efHk%A
nsohjkiks vxzsxqoks vxzsioks xz bee?k ;K u;rkxzs ;bifra lq/kkrq ;Kifra nso;qoe~AA YV.I,12 AA
This mantra (hymn) states that the substances like water, air etc. get polluted and if they will be
broken into minute articles by fire (with the help of yajna) they will get purified and pure rainfall
will occur. The hymn VI.10 of the Yajur Veda states that the materials used in yajna get divided
into minute atomic forms due to attraction of Sun and ascend to sky. This causes plenty of rain
fall. Likewise hymns VI – 16 and XIII – 12 of the Yajur Veda also reveal the same fact as:
vika is#jL;kiks nsoh% LonUrq lokRra fpRln~nsogfo%A
la rs izk.kks okrsu xPNrksZ leM~xkfu ;t=S% la ;Kifrjkf”k’kkAA YV.VI,10 AA
In the Vedas at several places, the mist has been given the appellation of uhgkj (Vajasaneyi
Samhita 17.31) as:
u ra fonkFk ; bek ttkukU;?kq’ekdeUrja cHkwoA
uhgkjs.k izkork ty~ik pkluIk mDFk”kkl”pjfUrAA VS.XVII,31 AA
The Yajur Veda knew about the immense concentration of mist or fog on water bodies and
oceans “thou are ocean full of mist”. It was also known that pure waters purify all things through
rain “May waters, like mother purify our bodies (YV.IV.2-3).
vkiks vLekUekrj% “kq/kz;Urq ?k`rsu ?k`rIo% iquUrqA
fo”o fg fjiza izogUr nsoh%A
mfnnkHk;% “kqfpjk iwr ,fenh{kkrilksLruwjfl
rka Rok f”kok “kXek ifj n/ks Hknza o.kZ iq’;u~AA YV.IV.2 AA
The Sun was known to be the disperser of clouds and cause of rain “O Sun, thou bring rain on
different parts of the earth”
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eghuka I;ksfl opksnk vfl opksZ es nsfgA
o`=L;kfl duhudjp{kqnkZ vfl p{kqesZ nsfgaAA YV.IV,3 AA
The Sam Veda gives more emphasis on wooing Rain God. It clearly says that the eternal power
of Sun penetrates the clouds and thus causes rain (SV. Previous II. 179). It also reveals that the
Sun pours rain water on moving earth with the help of wind (SV. Previous II. 148) as;
;fnUnzks vu;kfnzrks eghj;ks o’kUri%AA
r= iw’kk HkqoRlpkAA SV.Previous II.179 AA
bUnzks n/khpks vLFkfHkoZ =k.;izfr’dqr%A
t/kku uorhuZoAA SV. Previous II. 148 AA
The other verses of Sam Veda (V.562; final V.906; and final X.1317) discuss the kindness and
greatness and power of God along with the process of rain. Verse SV. Final, XX.1802 clearly
mentions the creation of oceans, rivers etc. due to the heavy rain by God.
vlkfo lkseksZ v#’kks o`’kk gjh jktso nLeks vfHk xk vfpØnr~A
iqukeks okjeR;s’;O;;a “;suks u ;ksfu ?k`roUreklnr~AA SV. Previous,V.562 AA
vk ioeku lq’Vqfr of’V nsoksE;ks nqo%A
b’ks ioLo la;re~AA SV.Final,V.906 AA
Ro flU/kw [kkl`tks/kjkpks vgUufge~A
v”k=qfjUnz tfKls fo”oa iq’;fl ok;Ze~A
rURok ifj ‘otkegs uHkUrkeUFkds’kka T;kadk vf/k/kUolqAA SV.Final,XX.1802 AA
In Atharva Veda we come across the similar concepts and hydrologic knowledge as contained
inthe other Vedas. Verse (I,4.3), for example, states as:
33
viks nsoh #ia g~o;s ;= xko% fioUr u%A
flaU/kqHk;% dRoZ gfo%AA AV.I,4.3 AA
This verse reveals the concept of evaporation due to heating by Sun rays and subsequently life
giving rainfall. The Prithvi Sukta of the Atharva Veda (XII,1.51) speaks of a violent dusty storm
which uprooted trees and calls it as ekrfj”ok:
;ka f}ikn% if{k.k% lairUr galk% lqi.kkZ% “kdquk o;kaflA
;L;ka okrks ekrfj”;s;rs jtkafl d`.oaP;ko;a”p o`{kku~A
okrL; izokeqiokeuq okR;fpZ%AA AV.XII,1.5 AA
The various hymns of the Rig Veda indicate that the Vedic literature mythically describes the
Indian atmospheric phenomena, especially those of the monsoons and rainy season, and the
violent thunderstorms by which they are usually accompanied.
Following the Rig Veda, the Satpatha Brahmana also recognizes sixty three winds (SB Part I,
2.5.1.13). The same text calls hoar frost as i `”ok-
f=% iz’VRok e#rks oko/kkuk mL=k bo jk”k;ks ;fK;kl%A
mi Rose% d`f/k uks Hkkx/ks;a “kq’ea r ,uk ºfo’kk fo/kseAA RV.VIII,96.8 AA
The Taithiriya Aranyaka (I.9.8) says that there are seven types of air currents or winds in the
atmosphere which produce seven types of clouds of the same appellation. These are (1) ojkºo ¼2½
Loril ¼3½ fo/kqUegl ¼4½ /kwie ¼5½ “oki; ¼6½ x`ges?k and (7) vkf”kfefof}’k- The ojkºo creates circumstances
which are responsible for condensation and good rainfall. The Loril is that whose temperature
condition is little affected by the insolation or Sun and perhaps occurs at a higher altitude and is
responsible for precipitation. The actual text of the mantra is as follows:
rkruqØfe’;k;% ojkoLLoril% A fo?kqUe; lks /kwi;%AA
“oki;ks x`ges?kk”osR;srs A is psesf”kfefof}i%A
itZU;kLlIr ifFkohefe oj’kfUr A o`’VfHkjfrAA Tai.Ara.,I,9.8 AA
The fo?kqUegl gives rise to thunderstorm; the /kwi; possesses some latent property or aroma which
it imparts to the objects with which it comes in contact, expanding quickly and the x`ges/k affects
the humidity or moisture content of the atmosphere. Theses six belong to a single genus and have
34
a single or similar region of activity. The vkf”kfefnf}’k belongs to another genus and its
geographical realm or region is different from the preceding six; however, it is highly favourable
for agricultural purposes. These seven classes of clouds bring rainfall with seven types of winds.
In verse I.10.9 of the Taithiriya Aranyaka, two more types of clouds are mentioned
(Tai,Ara,I,10.9). These are: ¼1½ “kEcj or “kkEcj and ¼2½ cgqlksexh- The former is responsible for profuse
rainfall, and the later is identified to be “the moving nimbus fall of water”. Thus, total nine types
of clouds with their properties, have been identified in the Taithiriya Aranyaka.
lforkja forUoUre~A vuqo/ukfr “kkEoj% A vkiiwj’kECj”oSoA
lforkajsilksHkDrAA I,10.8 AA R;a lqrIra` fofnRoSoA
cgqlksexhja o”khAA vUosfr rq;ksokfØ;ka re~A vk ;lw;kU”lkser`Ilw’kqAA Tai,Ara,I,10.9 AA
On the similar lines, during the age of epics we get information regarding clouds, rainfall,
evaporation, snow, storms etc. Verse VII.4.3 of Ramayana speaks of three kinds of clouds - czkge
(Produced from Brahma), vXus; produced from fire and i{kt (produced on a mountain flank).
White, red, blue and grey clouds are also referred to in the epic (V.1.81) as:
ik.MqjkL.ko.kkZfu uhyekfTe’Bdkfu pA
dfiuk d’;ek.kfu egkHkzkf.k pdkf”kjsAA Ramayana V,1.81 AA
gfjrkL.ko.kkZfu egkHkkf.k pdkf”kjsAA Ramayana V,57.7 AA
Climatic vagary or absence of rainfall is referred to in Ramayana (I.9.9) as:
vuko`f’V% lq?kksjk oS loZyksdHk;kogkAA Ramayana I,9.8 AA
vuko`’B;ka rq o`Rrk;ka lekuh; izo{;frAA Ramayana I,9.9 AA
Here, it speaks indirectly of atmosphere free from dust, fog, frost and mist. Similarly, the
condition of nocturnal sky (the moon from uhgkj or mist) is alluded to in Ramayana (I.29.25), as:
“k”kho xruhgkj% iquoZlqlefUor%AA Ramayana I,29.25 AA
Mist and its disappearance through diurnal rise of temperature is referred to in I,55.25 verse of
Ramayana, mist and severe cold in III, 16.12, cold western wind made still colder due to the
effect of him (frost) in III, 16.15, very dense mist in the vicinity of earth surface in III, 16.23,
35
water vapour hanging on the surface of the river structure in III.16.24, dew formation on the
sandy margins of the bank in III,16.24 and snowfall in III,16.25. These verses are given here as:
onrkS oS ofl’BL; ;k HkSfjfr eqgqeqZgq%A
uk”kk;kE;?k% xk/ks;a uhgkjfeo HkkLdj%AA Ramayana I,55.25 AA
fuo`Rrkdk”k”k;uk% iq’;uhrk fgek#.kk%A
“khro}rjk;kekfL=;kuk ;kfUr lkEizre~AA Ramayana III,16.12 AA
izdR;k “khryLi”kksZ fgefo}”p lkEizre~A
izokfr if”peks ok;q% dkys f}xq.k”khry%AA Ramayana III,16.15 AA
vo”;k;reksu}k uhgkjrelkork%A
izlqIrk bo y{;Urs foiq’;k oujkt;%AA Ramayana III,16.23 AA
ok’ila{kUulfyyk #rfoKs;lkjlk%A
fgefnzokyqdSLrhjS% lfjrks HkkfUr lkEizre~AA Ramayana III,16.24 AA
rq’kkjirukPpSo enqRokn~ HkkLdjL; pA
“kSR;knxkxzLFkefi izk;s.k jloTtye~AA Ramayana III,16.25 AA
Verse IV,1.15 of Ramayana states about the mountain winds. In another Verse (VI, 78.19) we
read about dusty, dry and gusty wind. Later on violent storm or tornado is also mentioned in
Ramayana (VI,106.21, okrk e.MfyuLrhok%½.
“kSydanj fu’ØkUr% izxhr bo pkfuy%AA Ramayana IV,1.15 AA
Like the Ramayana, the epic Mahabharata also contains valuable information related to
hydrosciences. In the twelfth skanda of the epic, atmosphere is divided into seven regions
(skanda, sphere, XII,328.31) and are discussed in considerable detail as “that wind which is the
first in above number and which is known by the name of izog drives, along the first course,
masses of clouds born of smoke and heat. Thus, during this time, the constituents of cloud were
also predicted. This wind passes through the sky and comes into contact with water in the clouds
(MB.XII,328.36) as:
36
i`fFkO;k;Urfj{ks p ;= laokUr ok;o%A
lIrSrs ok;qekxkZ oS rku~ fuoks/kkuqiwo Z”k%AA MB.XII,328.31 AA
izsj;R;Hkzla/kkrku /kwetka”pks’etka’o ;%A
izFke% izFkes ekxZs izogks uke ;ksfuy%AA MB.328.36 AA
The second wind called vkog] blows with a loud noise (MB. XII329.37). The wind which drinks
up water from the four oceans and having sucked it up, gives it to the clouds, presents them to
the Gods of rain, is the third in number and is known as mRng (MB. XII328.38-39-40).
vEcjs LusgeE;sR; fo/kqnHk;”p egk?kqfr%A
vkogks uke laeokfr f}rh;% “oluks unu~AA MB.XII,328.37 AA
mn;a T;ksfr’kka “k”or lkseknhuka djksfr ;a%A
vUrnsZgs’kq pksnkua ;a onkUr euhf’k.k%AA MB.XII,328.38 AA
;”prqHk;Z% leqnzsHk;ks ok;q/kkZfj;rs tye~A
m}R;knnrs pkiks thewrsE;ksEcjs fcyAA MB,XII,328.39 AA
;ksfnHk% la;ksT; thewrku itZU;k; izFkPNfrA
mRnrks uke cafg’BLr`rh;% l lnkxfr%AA MB,XII,328.40 AA
The winds which support the clouds and divides them into various parts, which melts them for
pouring rain and once more solidifies them, which in perceived as the sound of roaring clouds,
is known by the name laog- Fifth layer is called foog and the sixth is referred to as ifjog. The
seventh called ijkog (MB.XII.328.41-42-43-47-48) refers perhaps to some cosmic region.
lewg;ekuk cgq/kk ;su uhrk% i`Fkd ?kuk%A
o’kZeks{kd`rkjEHkkLr s HkofUr ?kuk?kuk%AA M.B.XII,328.41 AA
lagrk ;su pkfo}k HkofUr unra unk%A
j{k.kkFkkZ; lEHkwrk es?kRoeqi;kfUr pAA M.B.XII,328.42 AA
;ks lkS ogfr Hkwrkuka foekukfu fogk;lkA
prqFkZ% laogks uke ok;q% l fxfjefnu%AA M.B.XII,328.43 AA
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nk#.kksR;krlapkjks uHkl% Lruf;RuqekuA
iTpe% l egkosxks foogks uke ek#r%AA M.B.XII,328.48 AA
‘k’B% ifjogks uke l ok;qtZ;rka nj%AA M.B.XII,328.45 AA
;su Li`’V%ijkHkwrks ;kR;so u fuorZrsA
ijkogks uke ijks ok;q% l nqjfrØe%AA M.B.XII,328.52 AA
Here, at five places, the term wind used, actually implies a sphere or layer. These five names
also occur in Puranas and other later literature. The epic gives another classification of clouds
also giving four classes of clouds. The four types of clouds are laorZd] oykgd (MB,VIII,34.28),
dq.M/kkj (XII 271.6) and mrad (MB XIV 55.35-36-37). The oykgd clouds are formed in the foog
layer of atmosphere (described before). The clouds brining rainfall in desert area are called mrad-
These classification of clouds are different from those enumerated in Ramayana and Puranas.
lksFk lkSE;su eulk nsokuqpj;fUrdsA
izR;I”;Tty/kja dq.M/kkjeofLFkrae~AA MB,XII,271.6 AA
rnk ejkS Hkfo’;fUr tyiw.kkZ% I;ks/kjk%A
jloPp iznkL;fUr rks;a rs HkxquUnu]
mRrDM+es?kk bR;qDrk% [;kfr ;kL;fUr pkfi rsAA MB,XIV,55.36 AA
Around 600-700 BC, Kanada in his Vaisesika Sutra referred to the process of condensation and
dissolution of water (Vais. Sutr.V,2.8). He remarks “condensation and dissolution of water is
due to the conjunction with fire or heat”. About the phenomena of thunder, he observes that the
“rolling of thunder is a mark of the ingress of the light of the sky (Vais. Sutr.V,2.9)”, i.e. it is the
pealing of thunder which warrants the inference. He again says (Vais. Sutr. V, 2.11) that the
rolling of thunder results from conjunction with water and disjunction from a cloud. Here, it is
fully evident that the great sage knew that thunder is caused due to impact of positively and
negatively charged clouds.
vika lM~?kkrks foy;uTp rst% la;ksxkr~AA Vais. Sutr.V,2.8 AA
r= foLQwtZ FkqfyZM~xe~AA Vais. Sutr.V,2.9 AA
vika la;ksxkf}HkkxkPp Lruf;Ruks%AA Vais. Sutr.V,2.11 AA
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Discussing the falling of raindrops and flowing of streams, he further presents causes of falling
of water resulting from gravity in the absence of conjunction (Vais. Sutr.V,2.3) i.e. falling of
water in the form of rain, has gravity as its non-coinherent cause.
vika la;ksxkHkkos xq#Rokr~ ioue~AA Vais. Sutr.V,2.3 AA
In the verse V, 2.4, it has been said that the distant progression of the stream or great aqueous
whole composed by mutual conjunction of the fallen waters or raindrops, is produced by fluidity
as its non-coinherent cause and by gravity as its efficient cause.
nzoRokr L;Unue~AA Vais. Sutr.V,2.4 AA
The phenomena of evaporation, cloud formation, classification of clouds and their relationship
with winds or regions of atmosphere ¼okrLdU/k½ are also quite satisfactorily discussed in several
Puranas (Vayu Chapter 51, Li nga Vol.I, Chapt. 36, Matsya Vol.I, Chapt. 54). Describing the
general genesis of clouds, the Vayu Purana (51.22-25) says that there is moisture content in all
the movable or immovable objects of the world and due to insolation or Sun’s rays, evaporation
of that humidity takes place, and this process produces clouds. viz.
vkdZ rstksfgHkwrsHk;ksg;knRrs jf”eetZye~AA Vayu,51.23 AA
es?kkuka iqu#RifRrfL=fo/kk ;ksfu#P;rsA
vXus;k czg~etk”pSo o{;kfe iFkkfo/kk%A
f=/kk ?kuk% lek[;krkLrs’kka o{;kfe laHkoe~AA Vayu 51.28 AA
vXus;kLRo.kZtk% izksDrkLrs’kka rLekRizorZueA
“khr nqfnZuokrk ;s Loxq.kkLrs O;ofLFkrk%AA Vayu 51.29 AA
thewrk uke rs es?kk ;sHk;ks thoL; laHkok%A
f}rh;a izoga ok;q es?kkLrs rq lekfJrk%AA Vayu 51.36 AA
The above verses say that those clouds which give or sprinkle water are called es?k and which do
not bring any rainfall are known as vHk- There are three types of clouds (1) vkXus; (2) czg~et (3)
i{kt- These are connected with cyclonic (thermal and insolational), convectional (occurring in
northern continents, Siberia and equatorial regions) and orographic (occurring and proceeding
39
from mountain flanks) types of rainfall respectively. According to above mentioned Puranas,
vkXus; occurs in the winter season and it is devoid of lightening and thunder and is of immense
expanse and found in the mountain foots also. It brings rainfall within a radius of a mile or two.
This description approximates most to the Nimbus of modern days. The Brahmaja ¼czg~et½ clouds
are produced due to convection currents. In precipitation they cover an area of radius of nearly
a yojana (five or eight miles). Most probably these are cumulonimbus. The Puskara-Vartaka
¼iq’djkorZ½ clouds originate from or in the wings of mountains ¼i{klaHkok½- They assume various forms
and produce deep rumbling sound. They are full of profuse water and bring excessive rainfall
which is extremely destructive. This description conforms to a large extent to the modern class
of altostratus.
The Matsya Purana (Vol.I, Chap.54) furnishes still more elaborate and scientific information
regarding clouds. It says that the clouds thewr is the cause of life. These clouds remain suspended
on the air called Avaha. They change shape and goes up a yojana, from there form into rain hence
they are called the source of rain (Verse 10). If the shlokas 17,18 and 19 are interpreted
symbolically, they give other four classes of clouds expressed by the nomenclature xt] ioZr] es?k
and Hkksxh- Then in the Verse 17 can be recognized further four classes of xt clouds.
fo’kqon~xgo.kZ”p loZesrn /kqzosfjre~A
thewrk uke rs es?kk ;nsHk;ks tho lEHko%AA Matsya,I,54.9 AA
f}rh; vkogu ok;qesZ?kkLrs RofHklafJrk%A
brks;kstuek=kPp v/;}Zfod`rkvfiAA Matsay,I,54.10 AA
rs’kkeI;k;ua /kwe% losZ’kkefo”ks’kr%A
rs’kka Js’B”p itZU;”pRokj”psZo fnXxtk%AA Matsya,I,54.17 AA
xtkuka ioZrkukTp es?kkuka HkksfxfHk% lgA
dqyesdaa f}/kkHkwra ;ksfujsdk tya Le`re~AA Matsay,I,54.18 AA
Parjanys ¼itZU;½ and fnXxt rain in the season of gseUr and they are very useful for agricultural
growth is spoken in the verse below:
40
itZU;ks fnXxtk”pSo gseUrs “khrlEHkoe~A
rq’kkjo’kZ o’kkZfUr o}ka g~;Uufoo};sAA Matsya,I,54.19 AA
Process of condensation and precipitation on hygroscopic nuclei are very carefully described in
a nutshell in the Matsya Purana (I,54.33) as:
fu;PNR;kiks es/ksHko% “kqDyk% “kqDySLrqjf”efHk%A
vHkzLFkk% iz;rUR;kiksok;qukleqnhfjrk%A Matsya,I,54.33 AA
Meaning: “the waters from the (vapours) of the clouds when brought into contact with the wind
(namely hygroscopic content of the air) fall in the shape of rain”.
The Vishnu Purana (II,9.11-12) very scientifically enumerates the four sources of atmospheric
moisture, “the glorious Sun, O Maitreya, exhales moisture from four sources, namely – seas,
rivers, the earth and living creatures,”. viz.
vHkzLFkk izirUR;kiks ok;quk leqnhfjrk%A
laLdkja dkytfura eS=S;klk?k fueZyk%AA Vishnu,II,9.11 AA
ljRlleqnzHkkSekLrq rFkki% izkf.klEHkok%AA
prq’izdk”k HkxokuknUrs lfork equsAA Vishnu,II,9.12 AA
The celebrated poet Kalidasa (100 B.C.) also knew a lot about clouds and the allied phenomena.
He defines cloud thus “it is an assemblage of smoke, electricity, water and air” (Purvamegha
Verse 5). At other places (Purvamegh, Verse 6) the poet names two types of clouds namely iq’dj
and vkorZd
/kweT;ksfr% lfyye#rkaa lUuikr% Od es?k%A
lUns”kkFkkZ Od iVqdj.kS% izkf.kfHk% izki.kh;k%AA Meghadutam,Purvamegha.5 AA
tkra oa”ks Hkqoufofnrs iq’djkorZdkuka tkukfe Roka izdfriq#’ka dke#ia e?kksu%AA Purvamegha Verse 6 AA
The Mricchakatika (600 AD) refers to a kind of cloud nzks.k (X.26) from which the rain streams
forth as from a bucket. In another context, the famous drama refers to a special type of rain
nzks.kof’V streaming forth as from a trough (X.39) viz.
41
dks;esoafo/ks dkys dkyik”kkfLFkrs ef;A
vuko`f’Vgrs lL;s nzks.kes?ka boksfnr%AA Mricchakatika, X.26 AA
ds;eHk;q?krs “kL=s eR;qoD=xrs ef;A
vuko`f’Vgrs lL;s nzks.kof’VfjokxrkAA Mricchakatika,X.39 AA
Four types of clouds in all have been spoken of by Kalidas. They are vkorZ] laorZ] iq’dj and nzks.k-
The Avarta brings no rainfall; the Samvarta gives an abundance of rain, the Puskara causes flood
of rain and the Drona is most congenial to agriculture and mankind. This is stated in nutshell in
the following lines –
vkorksZ futZyks es?k% laorZr”p ogwnd%A
iq’djks nq’djtyks nzks.k% “kL;iziwjd%AA
Kalidas Granthavali, Abhidhan Kosh, P.154 AA
In the library (Saraswati Bhavan Pustakalaya) of Sampurnand Sanskrit University, Varanasi a
manuscript treatise entitled as es?kekyk is available. As the very name suggests, it is a work on
climatology and more specifically science of clouds. On the basis of content and style of dialogue
Tripathi (1969) tried to establish that Meghamala is a part of #nzk;ekyra=e~ (around 900 AD
around). es?kekyk has 11 chapters. The first chapter of es?kekyk opens with the enquiry
es?kLrq dhn`”kknso dFka fo|qRiztk;rsA
dhn`”ka o.kZ:ia rq “kjhj rL; dhn`”ke~AA
(Meghamala, Manucript No. 37202, Sampurnand Sanskrit University, Varanasi)
The first chapter deals with what are clouds, how lightning is produced, what are nature, texture,
ingredients and colours of clouds. Later in the Verse 20,21,22 is expressed, in their conventional
Indian style, that the mountains control clouds. From Verses 32 to 68 we gather that there is a
larger division of clouds comprising twelve species and designated as 1- lqcq/k 2- uUn”kkyk 3- dU;n
4- iFkqJok 5- oklqnh 6- r{kd 7- odrZ 8- lkjor 9- gsedkyh 10- tysUnz 11- otzna’V and 12- fo’.kqizHk- But no
scientific detail of these is furnished. The Chapter II enumerates various types of years, refers to
their rainfall and discusses the economic characteristics or conditions of each of them. The IIIrd
chapter dwells on astrological influence on rainfall, climatology and economic condition of
people, state of plenty and scarcity and production of various crops. VIIIth chapter aspires to
42
discuss the nature of rainfall and other meteorological conditions in the twelve months of the
year. About the Kartika (October – November) the author says that during this month scattered
clouds of varied colours occur. In Pausa (December – January) if sky is over cast with clouds, it
is a very good symptom. If the month of Magha (January – February) is not normally cold (or
has no frost) there occurs scanty rainfall in Phalaguna (February – March) northeast wind brings
good downpour.
ekfl ekfl dFka nsfo dhn”ka xHkZy{k.ke~A
fda okra fda ?kua ;qDra dL; dkysu o’kZfrAA
dkfrZds “kqDy uUnk;ka iTp#ikf.k ;ks Hkosr~A
vHkzkf.k “osro.kkZfu jDr.kkZfu ;ks HkosrAA
ifro.kkZfu ;ks es/kk fg d’.ko.kZ”p Hkosr~A
dkaL;o.kksZ Hkos?kLrq rkezo.kZLrFkk Hkosr~AA
u ek?kksifrra “khra T;s’Bs ewya u o`f’Vd`r~A
uknkZ;ka ifrra rks;a nq’VdkyLrnk Hkosr~AA
rnk nsfo Hkfo’;fUr lqfHk{ka {kseoso pA
iwoksZRRjtokrsu jk=~;Urs tyeqRre~AA Meghmala, Page 14-38 AA
In the chapter IX of Meghmala there is discussion on clouds, winds and lightning. Firstly, it
discusses the correlation of rainfall with different shapes and directions of lightning. Then we
are told that north-east wind is conductive to prosperity, southerly does good to people, south-
west wind causes misery, westerly is much beneficial for the higher production of rice, northerly
is also favourable to the good of people, and it produces a condition of plenty.
iwosZ fo/kqRdjkes?kk vfXu; ~;ka ty”kksf’k.khA
nf{k.ks jkSjoa ?kksja uS_R;ka rkiekfn”ksr~AA
“kqfHk{ka iwoZokrsu tk;rs ik= la”k;%A
nf{k.ks rq {ksedjks uS_R;ka nq% [knks HkosrAA
ok#.;ka fnR;a/kkU;kfu ok;R;kaok;q[ks Hkosr~A
mRrjs “kqHknks nsfo ,s”kkU;ka loZlEin%AA Meghmala, Page 47-48 AA
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The chapter X of Meghmala deals with the propitiation of clouds and apart from repeating the
twelve species of clouds, already mentioned, adds another classification of the same comprising
seven species designated as vEcqn] xksyd] fxfj] vkjksid] lioZr] f[kf[kUn and dksfVokj-
The encyclopedic Tantrik literature also does not lag behind in supplying information on
hydrology. From the Tantraloka of Abhinavagupta, we can find out some important
climatological and meteorological facts. In its Ahnika designated as ns”kk/oizdk”ku are described
winds, clouds, track of winds and the allied phenomena (Vol. V of the Tantraloka) (Tripathi,
1969). It refers to ten air channels ¼ok;qiFk½ which are perhaps peculiar to only this text. Those ten
air channels are 1- foro 2- _rkf)Z 3- otzkbd] 4- oS|qra 5- jSor 6- fo’kkorZ ¼nqtZ;½ 7- ijkog 8- vkog 9- egkog
and 10- egkifjog (Vol. V,121.138). These are arranged in space according to increasing height.
The outstanding Tantrik work recognized ten types of clouds 1- ewdes?k 2- izkf.ko’kksZa 3- fo’kokfjo’khZ 4-
LdkUn 5- laorZ 6- czkge 7- iq’dj 8- thewr 9- bZ”kdr] and 10- egsf”kdr ¼dikyksRFk½- These types also occur
according to the increasing height. It is perhaps for the first time in Indian literature that
establishes the height of clouds. It reveals that different clouds occur at different level in the
atmosphere.
The Jain literature also made a considerable contribution in the field of meteorology. The
‘Prajnapana’ and ‘Avasyaka Curnis’ provide outstanding references to the various types of winds
(Tripathi, 1969). The Avasyaka Curnis furnish a list of fifteen winds (9-7/913) as: 1- izkphuokr
(easterly) 2- mnhphu (northerly) 3- nf{k.kokr (southerly) 4- mRrj ikSjLR; (northerly blowing from the
front) 5- lokRlqd (undefined) 6- nf{k.k iwoZrqaxj (southerly strong wind) 7- vijnf{k.kchtk; (blowing
from the south-west) 8- vijchtk; (westerlies) 9- vijksRrxtZu (north-westerly hurricane) 10-
mRrjlokRlqd (unknown) 11- nf{k.k lokRlqd 12- iwoZrqaxj 13- nf{k.k and if”pe chtk; 14- if”pextZHk (western
storm) 15- mRrjhxtZHk (northern strom). Later in the same continuation tornadoes are referred to as
dkfydkokr- This vocabulary had influenced the Arabian geographers and navigators and they
readily absorbed several of these Indian technical terms in their own language (Motichandra,
‘Sarthavaha’ (Hindi), P.202).
The ‘Prajanapana’ also refers to snowfall ¼fge½ and hailstorm ¼djd½ (I.16). The ‘Trilokasara’
(Passage 679, P.280) of Nemichandra says that there are seven types of dkyes?k (periodic clouds).
They rain for seven days each in the rainy season. Then there are twelve species of white clouds
44
designated as nzks.k. They also bring rain for seven days each. Thus, the season of rainfall extends
over 133 days in all.
The Buddhist literature also throws significant light on meteorology. In the narrative of the first
Jataka, named ‘Apannaka’, several climatological facts are described. In ‘Migalopajataka
(Cowel, Eng. Trans. Vol.III, P.164.), two violent storms are mentioned as dkyokr (black wind)
and csjEcjkr (Tripathi, 1969). The latter is said to belong to the upper air (Samyutta Nikaya, Eng.
Trans. XVII. 1-9, P.157). The Sumeru mountain was frequently visited by a violent hurricane
¼mRikVuokr or gj.kokr½ (Mahamorajataka No. 491, P.333; Harit Jataka No. 431, P.497). It
resembled whirlwind in movement. In ‘Milinda Panho’ hot wind or Loo is spoken of as okrkri
(Eng. Trans. Vol.II,IV,6.35, P.86). ‘Aryasura’ names four types of winds fu;rkfuy (Monsoon),
p.Mkfuy (tempest), mRikrokr (hurricane) and Ik”pkR;ok;q (westorlies) (Jatakamala, ed. by H. Kern,
10.29, P. 90, 127, 133). In the ‘Vinaya Pitaka’ (III, V.9.4,P.85), whirlwind is called okre.Myhdk-
The Divyavadana’ speaks of some kinds of hurricane as dkfydkokr (Vol.II,P.41), and of storm
accompanied by rain as okro’kZe (Vol.II,P.163).The ‘Milindapanho’ (IV.1.36) says that there are
four types of rainfall: 1. of rainy season 2. of winter season, 3. of the two months vk’kk<+ and Jkou
(July and August), and 4. rain out of season. At a glance, it can be seen that the classification is
fully scientific.
The Buddhist literature refers to two general classes of clouds as: dkyes?k (monsoon cloud) and
vdkyes?k (storm clouds or accidental ones) (Mahavastu Vol.II, P.34, Tripathi, 1969). The
Samyutta Nikaya classifies clouds into five categories (Vol.III, Book XI, 32.1.1, P.200), 1-
“khroykgd (cool clouds),2. Å’.koykgd (hot clouds) 3- vHkzoykgd (thunder clouds, it can be identified
with cumulus), 4- okroykgd (wind clouds – perhaps clouds formed due to the activity of
convection current in the atmosphere) and 5- o’kZoykgd (rain clouds – most probably
cumulonimbus which brings copious downpour of rain).
Thus, we see that the Jain and Buddhist texts (before 400 B.C.) have a very scientific
classification of clouds and winds that can be compared with the modern meteorology. So much
of subtle observation at such an early date is a golden achievement of ancient times.
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Variation of Rainfall
According to the Matsya Purana, to the north and south of the snow-clad mountains ¼fgeor½
occurs the iq.Mª cloud which greatly increases the stock of rain. All the rain formed there converts
itself into the snow. The wind on the fgeor draws by its own force those snow flakes and pours
them on the great mountains. Beyond the fgeor there occurs little rain (Matsya, I,54.22-25).
“kdhjku lEizHkqTofUr uhgkj bfr l e`r%A
nf{k.ksu fxfj;ksZlkS gsedwV bfr Le`r%AA Matsya,I,54.22 AA
mnxfgeor% “kSyL;ksRrjs pSo nf{k.ksA
iq.Ma uke lek[;kr lEoxof’V foo};sAA Matsya,I,54.23 AA
rfLeu izorZrs o’kZ rUrq ‘kkjleqnzHkoe~A
rrks fgeorks ok;qfgZea r= leqnzHkoe~AA Matsya,I,54.24 AA
vku;R;kReosxsu flfTo;kuks egkfxfje~A
fgeoUrefrØE; o`f’V”ks’ka rr% ije~AA Matsya,I,54.25 AA
Thus, there is a reference to a very important geographic fact of scanty rainfall or arid condition
of the Tibetan plateau. The study and knowledge of this fact is really creditable on the part of
those ancient Indians. The Linga Purana (Vol. I,36.38.39 and 49) says “it is the izog wind or air
current which makes the clouds produced by smoke and thermal activity full of water, so that
the clouds Puskara ¼iq’dj½ and i{kt give copious rainfall”.
nUng~;;ekus’kq pjkpjs’kq xks/kweHkwrkLRoFk fu’ØekfUrA
;k ;k Å/oZ ek#rsusfjrk oS rkLrkLRoHkzka;kfXuukok;quk pAA Lings,I,36.38 AA
vrks /kwekfXuokrkauka laa;ksxLRoeqP;rsA
okjhf.k o’kZrhR;HkzeHkzL;s”k% lgL=n`d~AA Linga,I,36.39 AA
fofjpksPN oklrk% losZ izogLda/ktkLr%A
i{ktk% iq’djk?k”p o’kkZfr p ;nk tye~AA Lings,I,36.49 AA
46
Modern meteorology tells us that polar winds actually never bring any rainfall in the year in the
region under their influence – flanking poles or Tundra, and only scanty summer rain occurs in
those areas due to the sweeping of strong westerlies. The same fact is stated in the Puranic line,
/kqzos.kkf/kf’Brks ok;qfoZf’Va lagjrs iqu%AA Matsya,Vol.I,54.36 AA
Meaning: the air from the Pole drives away the rain,
The Vrhat Samhita and Mayuracitraka by Varahamihira are two very important treatises which
are replete with climatological and meteorological information. Although they abound in
astrological guesses, they contain sufficient scientific facts also. In the Vrhat Samhita, there are
three chapters (21st, 22nd, and 23rd) on climatology and meteorology and they treat the subject in
their own ancient conventional style. Here only the salient features of the chapters are being
presented.
The verses 23 and 24 of the chapter 21 of Vrhat Samhita state that extremely white or dark clouds
resembling aquatic animals like huge fish, shark or tortoise and seen before the rainy season are
a source of abundant rainfall viz.
eqDrkjtrfudk”kkLrekyuhyksRiyTtukHkkl%A
typjlRokdkjk xHksZ’kq ?kuk% izHkwrtyk%AA Vr.S.21.23 AA
rhozfnokdjfdj.kkfHkrkfirk eUnek#rk tynk%A
#f’krk bo /kkjkfHkfoZltUR;EHk% izlodkysAA Vr.S.21.24 AA
The verse 31 discusses the conditions or meteorological ingredients which determine the spatial
expanses of rainfall, though it appears to be of little value from modern meteorological point of
view.
iTpfufeUrS% “kr;kstua rn}kZ}ZesdgkU;kr%A
o’kZfr iTtfufeRrknwzis.kSdsu ;ks xHkZ%AA Vr.S.21.31 AA
47
From chapter 22, it is gathered that fleecy and thick clouds give abundant rainfall which is very
congenial to agriculture. Again, if clouds situated in the east, south and north sail towards south,
west and north respectively, they cause fine and copious rainfall.
jfopUnzijhos’kk% fLuX/kk ukR;Urnwf’krk%A
o`f’V’rnkfi foKs;k loZlL;kFkZlkf/kdkAA Vr.S.22.7 AA
es?kk% fLuX/kk% lagrk”p iznkf{k.kxfrfØ;k%A
rnk L;kUegrh o`f’V% loZlL;kfHko`};sAA Vr.S.22.8 AA
In the Mayuracitraka, it is stated that scattered clouds devoid of lightning are harmful to people
and those of red and white silken or golden or Kraunca bird’s hue, embedded in the atmosphere
and fleecy in texture are always beneficial to the people. Causation of fog or mist in Pausa
(December–January) is conductive to good rainfall. (Sampurnanand Sanskrit University,
Library, Manuscript No. 34332, Page 36-37).
ikS’kL; d`’.klIrE;ka uHkks foeyrkjde~A
LokR;ka rq’kkjikr%L;kr Jko.ks r= o’kZ.ke~AA
Discussing the conditions determining rainfall, it says that if there is no frost in Magha (January–
February), no vigorous wind in Phalguna (February – March), no clouds in Chaitra (March–
April), no hailstorm in Vaisakha (April–May) and no scorching heat in Jyestha (May–June),
there is insufficient rain in the rainy season (Above manuscript, Page 17 -18), viz.
ek?ks fgea u irfr okrk okfUr u p Qky~xqusA
u p /kwekf;ra pS=s ?kuSuZHkLrra u rqAA
dkjdk eksp u oS”kk[ks “kqØs p.Mkriks u fgA
rnkfrrqPNk o`f’V% L;kr~ izko’Vdkys u la”k;%AA
If Sun is hot in the morning, its light during the day is of yellowish hue and clouds are fleecy
and dark-coloured, the conditions result in good rain. Similarly, if the Sun is hot in the morning
or at the time of rising and scorching at noon and clouds have a pigment of molten gold, rain
occurs during the very day (above manuscript, Page 18).
48
izko`Vdkys ;nk lw;ksZ e/;kUgs nq% lgks Hkosr~A
rn~fnus o`f’Vn% izksDrks Hk`”ka Lo.kZleizHk%AA
If water appears to be dull, clouds are of the shape of mountain, quarters are clear, the sky is of
the hue of crow’s egg, there calm in the atmosphere and aquatic animals like high and others
disappear in the bottom and grogs make loud noise, very fine and copious rainfall comes soon
(Manuscript No. 34332, Page 18). Further, if the texture of the clouds resembles the wings of a
Partridge, rainfall occurs.
;nk tya p fojl xksus= lfUufHk%A
fn”k”p foeyk% lokZ% dkdk.MkHka ;nk uHk%AA
u ;nk okfr riu% iou% LFkya ;nkA
“kCna dqoZfUr e.MwdkLrnk L;kn~ o`f’VdRrekAA
Thus, it is evident that Mayuracitraka has attempted to formulate principles for forecasting
rainfall variation through the observation of natural phenomena and the synchronization and co-
relationship of the two. The symptomatic synchronization in the realm of nature is often
governed by laws having mathematical accuracy in which intuition of the animate (birds and the
animals) and scientific cause and effect relationship of events form the accurate base, provided
the observation has been made very carefully. In those ancient days, when advanced meteorology
and its complicated computations, computers and other cybernetics and servo-mechanic
contrivances were unknown, this was of special significance and most probably the only method.
Measurement of Precipitation
The amount of precipitation in the form of rain is usually determined from the accumulation of
water collected in a rain gauge; and several types of recording instruments are routinely
employed for the purpose. There are strong proofs to establish that the system of measuring
rainfall was introduced by the Mauryan rulers in the Magadha country (south Bihar) in the fourth
or third century B.C. and they are credited with the establishment of first observatory. The system
was continued to be practised effectively by the succeeding rulers until the end of the sixth
century A.D. (Srinivasan et al., 1975).
During the Mauryan period, the raingauge was known as o’kkZeku- Kautilya describes its
construction in these words “In front of the store house, a bowel (Kunda) with its mouth as wide
49
as an aratni (24 angulas = 18” nearly) shall be set up as raingague ¼o’kkZeku½ (Arthasastra, Book II,
Chapt. V, P.56 Shamasastry). A schematic of the modern raingauge is shown in Figure 3.2. By
comparing the dimensions of the ancient Indian and Symon’s raingauge, one can easily infer
about the level of knowledge possessed during that period.
Figure 3.2: The Symon’s raingauge (Modern raingauge) (Source: Raghunath, 2006)
The distribution of rainfall in various areas was well known at that time. A reference from
Kautilya’s Arthshatra can be cited here as: “'The quantity of rain that falls in the country of
jangiila (desert countries or countries full of jungles)is 16 dronas; half as much more in
anupanam (moist countries); as the countries which are fit for agriculture (desavapanam); 13.5
dronas in the countries of asmakas (Maharashtra); 23 dronas in Avanti (probably Malwa); and
an immense quantityin aparantanam (western countries, the countries of Konkan); the borders
of Himalayas and the countries where water-channels are made use of in agriculture”. Kautilya’s
method of classification of rainfall areas in relation to the annual average quantity is indeed
remarkable and he is the only classical author who treats this aspect in a nutshell covering almost
the whole of the Indian subcontinent (Srinivasan, 1975). From this, it is evident that the spirit of
the methodology of the measurement of rainfall given by Kautilya is the same as we have today,
the only difference is that he expresses it in weight measures (Arth. Chapt.XXIV, Book II, P.130)
while we use linear measure nowadays. Discussing the further geographical details of rainfall,
he observes “when one-third of the requisite quantity of the rainfalls, both during the
50
commencement and closing months of the rainy season, and two third in the middle, then the
rainfall is considered very even ¼lq’kqek#ie~½-
As can be easily expected out of the agricultural necessity, the science of forecasting the rains
had also come into existence and must have been developing empirically. It is further mentioned
in the book Arthshastra that “A forecast of such rainfall can be made by observing the position,
motion and pregnancy (garbhadhan) of Jupitar, the rising, setting and motion of Venus, and the
natural or unnatural aspects of the Sun. From the movement of Venus, rainfall can be inferred”.
Discussing the classification of clouds and interrelationship of rainfall and agriculture, it is
further added that “there are clouds which continuously rain for seven days; eighty are they that
pour minute drops; and sixty are they that appear with the Sun shine”. When rain, free from wind
and unmingled with sunshine falls, so as to render three turns of ploughing possible, then reaping
of good harvest is certain.
The author of Astadhyayi, Panini (700 B.C.) refers to the rainy season as izko’k (IV, 3.26; VI,
3.14) and o’kkZ (IV 3.18). The former was the first part of the season. These two parts were known
as iwoZ o’kkZ and vijo’kkZ ¼vo;okn_rks% VII 3.11). He also refers to o’kZizek.k (III, 4.32) as:
o’kZ izek.k vyksi”pkL;kU;rjL;ke~AA Astadhayai,III,4.32 AA
Citing examples for measurement of rainfall Panini further writes xks’iniza o`’Vks nso% (rain equivalent
to depression created by hoof of cow), lhrkiza o`’Vks nso% (rain equivalent to fill the furrow created
by indigenous plough). It is evident that the xks’in was the measure of the lowest rainfall.
Like Kautilya, Kanad and other precursor authorities such as Varahamihira also describe the
device of the father of the raingauge and tell us how to measure rainfall from it. In Verse 2 of
chapter 23, he states that constructing a circular bowl ¼dq.Mde~½ measuring one cubit, one should
tell the amount of rainfall, viz.
gLrfo”kkya dq.Mdekf/kdR;kEcqizek.kfunsZ”k%A
iTpk”kRiyek<+deusu feuq;kTtya ifrre~A Vr.S.23.2 AA
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For calculating rainfall he adopts weight measures of pala, drona and adhaka (4 vk<+d = 1 nzks.k =
200 iy] and 1 vk<+d = 7 lbs. nearly). For measurement, rain water received in the bowl during
the actual falling should be measured. The distribution of the rainfall according to time is
discussed in the verses 6,7,8 and 9. These verses of Vrhat Samhita specify the amount of rainfall
in various lunar mansions as:
gLrkI;lkSE;fp=kiks’.k/kfu’Bklq ‘kksM”k nzks.kk%A
“krfHk’kxSUnzLokfr’kq pRokj% dRrdklq n”k%AA Vr.S.23.6 AA
Jo.ks e?kkuqjk/kkHkj.khHkwys’kq n”k prq;qZDrk%A
QTxqU;k iTpd`fr% iquoZlks fo”kafrnzks.kk%AA Vr.S.23.7 AA
,sUnzkXU;k[;s oS”os p fo”kafr lkiZHks n”k =~;f/kdkA
vkfgcqZ/U;k;ZE.kizktkiR;s’kq iTpdfr%A Vr.S.23.8 AA
iTpn”kkts iq’;s p dhfrZrk okftHks n”k }kS pA
jkSnzs’Vkn”k dfFkrk nzks.kk fu:inzkos’osrsAA Vr.S.23.9 AA
In chapter XXXV, he says that phenomenon of rainbow is the result of spectro analysis of Sun’s
rays through clouds in the atmosphere. (XXXV.1)
lw;ZL; fofo/ko.kkZ% iousu fo?kkV~fVrk% djk% lkHkszA
fo;fr /kuq% laLFkkuk ;s n”;Urs rfnUnz/kuq%AA Vr.S.35.2 AA
Parasara knew the contrivance of primitive raingauge and method of measuring the quantity of
rain received (Vrhat Samhita, Chapt. 21, Garbhlakhsnadhyaya). viz.
vk<+dkT”prqjks nzks.kku;ka fo?kkr~ izek.kr%A
/kuq% izek.ka esfnU;ka fo?kkn nzks.kkfHko’kZ.ke~AA
prqfoZ”kkM~- xqykukgs f}prq’dkM- xqyksfPgrsA
Hkk.Ms o’kkZEoqlaiwZ.ksZ] Ks;ek<do’kZ.ke~AA Vr.S.between 21.32 and 21.33 AA
Epilogue:
From the various discussions presented in this chapter, we note that the knowledge related to
cloud formation, precipitation and its measurement was of outstanding order in ancient India.
52
Condensation of evaporated water which is facilitated by the presence of dust particles etc.
(which acts as nuclei as per modern meteorology), effect of yajna ¼;K½, forests, reservoirs etc. on
the causation of rainfall and the classification of clouds alongwith their colour, rainfall capacity
etc. are thoroughly described in ancient Indian literature like Vedas, Puranas, Vaisesika Sutra,
Astadhyayi, Arthasastra and Puranas. The forecasting of rainfall on the basis of natural
phenomena like colour of sky, clouds, lightening, rainbow etc. was noteworthy. The instruments
for measuring rainfall were developed and the principles were same as that of modern hydrology
except that weight measure of Drona, Pala etc. were used instead of modern linear measurement.
The Indus civilization was able to find the seasonal variations in rainfall and methods to check
the Indus floods. During the Mauryan period, it was possible to describe the distribution of
rainfall in different areas of India and they are credited with the installation of first observatory
worldwide. Modern meteorological facts like arid region of Tibetan rain shadow area and no
rainfall due to polar winds are fully advocated in Puranas. The Jain and Buddhist works guessed
the actual height of clouds. Knowledge of monsoon winds and their effects as conceived by
ancient Indians is in accordance to modern hydro-science. These facts show that there was
enriched knowledge of water science and associated processes, including meteorology during
ancient times in India, which is at par to the modern water science.
53
In the hydrological cycle, water which falls as rain reappears as infiltrated water, runoff, surface
and underground water storage. This is also called as rainfall partitioning in modern hydrologic
literature. The surface and ground water reservoirs are constantly getting replenished by recharge
(precipitation) and depleted by evapotranspiration. The concepts related to the various
components of rainfall partitioning were well conceived by the ancients Indians. This chapter
briefly discusses about the ancient knowledge in this field as available in the Vedas and other
ancient Indian literature.
Interception and Infiltration
Interception is the part of the rainfall that is intercepted by the earth’s surface and which
subsequently evaporates. Interception can amount to 15-50% of precipitation, which is a
significant part of the water budget. One can distinguish many types of interception, which can
also interplay with each other (Geritts, 2010). The term infiltration is used to describe the process
involved where water soaks into or is absorbed by the soil (Horton, 1933) and it is one of the
important components of the hydrologic cycle. In the hydrologic cycle, water from the oceans
and various surface bodies on the land evaporates and becomes part of the atmosphere. The
evaporated moisture is lifted and dispersed in the atmosphere until it precipitates on the land or
in the ocean. The precipitated water may be intercepted and used in transpiration of the plants or
may run over the ground.
Some references to interception are found intermixed with other topics in ancient Indian
literature, such as explaining the effect of forests and vegetation on rainfall, cloud formation and
environmental purification. Taithiriya Samhita mentions the effect of forests on causation of
rainfall (TS. II, 4.9.3)
lkSHk;;SokgqR;k fnoks of’Veo #U/ks e?kq’kk la ;kSR;ika
ok ,’k vks’k/khuka jlks ;Ue/oHkn; ,okS’k/khHk;ks o’kZR;Fkks
vn~Hk; ,okS’k/khHk;ks of’Va fu u;frAA TS,II,4.9.3 AA
Chapter-4
INTERCEPTION, INFILTRATION AND
EVAPOTRANSPIRATION
54
The verses 184.15-17 of Mahabharata state that the plants drink water through their roots. The
mechanism of water uptake by plants is explained by the example of water rise through a pipe.
It is said that the water uptake process is facilitated by the conjunction of air. This clearly reveals
the knowledge of capillary action of soil in movement of water up and down as:
iknS% lfyyikukPp~ O;k/khuka okfi n”kZukr~A
O;kf/kizfrfØ;RokPp fo?krs jlua nzqesAA MB.XII,184.15 AA
oD=s.kksRiyukysu ;Fkks/oa tyekn~nsrA
rFkk ioula;qDr% iknS% fiofr ikni%A MB.XII,184.16 AA
As far as infiltration is concerned, the scholar, Varahamihira clearly reveals it in the opening
shloka of the Vrhat Samhita. Verse I tells us that at some places water table is higher and at
others it is lower as:
iqalka ;Fkknsu f”kjkLrFkSo f{krkofi izksUurfuEulaLFkk% (Vr.S,54.1)
It implies that the water veins beneath the earth are like veins in the human body, some higher
and some lower. Verse 2 reads like this.
,dsu o.ksZu jlsu pkEHk”P;qra uHkLrks olq/kkfo”ks’kkr~A
uukjlRoa ogqo.kZrka p xra ijh{;a f{kfrrqy~;esoAA Vr.S.,54.2 AA
It says that the water falling from sky assumes various colours and tastes from differences in the
nature of earth. Thus, it implies that the infiltration of rainwater is the source of groundwater.
The ground water is a complex function of rainwater. Rainwater originally has the same colour
etc., but assumes different colours and tastes, after coming down to the surface of the earth and
after percolation.
Three verses quoted by Bapudeva Sastri (in Sindhanta Siromani by Bhaskaracharya, Part II,
Goladhayaya, Tripathi, 1969) belonging to an era prior to 1200 A.D., provide scientific details
of the phenomena of fog or mist (for which the term jt% lagfr has been used). The verses purport
to say that at the end of rainy season dissipated clouds (moisture) hang near the surface of the
earth and eclipse mountains, trees, vegetation cover or gardens and disappear through the activity
55
of air and heat from these surfaces. This clearly reveals the fact of interception by earthy
materials, vegetation etc. and its disappearance with time by the activity of air and heat.
Evapotranspiration
The phenomena of evaporation and evapotranspiration and its interrelation with other
hydrological processes were well understood by ancient Indians as evidenced by Vedic and other
ancient literature. In Rig Veda (I, 6.10) it is mentioned that the sun ray breaks the water contained
in the earth and other materials into minute particles, then these minute particles ascend by air
and form clouds as:
brks ok lkfrehegsZ fnoks ok ikfFkZoknf/kA
bUnz egksokj tl%AA R.V. I,6.10 AA
uO;a rnqDF;a fgra nsokl% lqizokpue~A
_re’kZfUr flU/ko% lR;a rkrku lw;ksZ foRra es vL; jksnlhAA R.V.I,105.12 AA
The verse I,105.12 of Rig Veda says that the water from the sea etc., evaporates due to the heat
of Sun rays, which is the primary cause of rain formation. The same fact is revealed in the verse
IV, 58.1 of Rig Veda as:
leqnzknwfeZeZ/kqeka mnkjnqika”kquk le`erRoekuV~A
?k`rL; uke xqg~;a ;nfLr ftOgk nsoukee`rL; ukfHk%AA R.V.IV,58.1 AA
The verse VIII, 72.4 of the Rig Veda says that the atmospheric air gets heated due to Sun, then
this heat reaches the Earth and converts the humidity into vapour and collects it as clouds, which
is the cause of the rain and food production as:
tkE;rhr;s /kuqoZ;ks/kk v#g}ue~A
/’knsZ ftg~ok;o/kkr~AA R.V.VIII,72.4 AA
Like Rig Veda, the Yajur Veda also contains some knowledge about evaporation along with
transpiration as:
nsoks ouLifrnsZofeUnza o;k/kla nsoks nsoeo/kZ;rAA Y.V.,28.43 AA
nsoks nsoSoZuLifr fgj.;;.kksZ e/kq”kk[k% lqfiIiyksa nsofeUnzHko/kZ;r~AA Y.V.,28.20 AA
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It says that the vegetation attracts water from Earth and evaporates it to the atmosphere due to
heat, wind etc. to form clouds. Similarly, Atharva Veda (IV, 25.2 and IV, 27.14) says that due
to universal Sun and air, the water goes to the sky and comes back as rain. The evapotranspiration
is caused due to Sun rays and wind as:
;;ks% la[;krk ofjek ikfFkZokfu ;kHk;ka jtksZ ;qfir;Urfj{ksA
;;ks% izk;a ukUoku”ks d”pu rkS uksZ eqTpreagl%AA A.V. IV.25.2 AA
vi% leqnzkn fnoeqnoagfUr fnoLi`fFkohefHk ;s l`tfUrA
;s vfHknjh”kkuka e#r”pajkfUr rs uks eqTpUragl%AA A.V. IV,27.74 AA
The versa I, 173.6 of the Rig Veda states that the atmosphere encompasses the Earth.
iz ;fnRFkk efguk uHk;ks vLR;ja jksnlh d{;s ukLeSA
la foO; bUnzks otua u Hkwek HkfrZ Lo/kkoka vksi”kfeo ?kke~AA R.V. I,173.6 AA
The solar phenomena are associated with the vault of the sky or heaven, while lightning. Rain
and wind are referred to as occurring in the atmosphere (R.V., IV, 53.5, III., 56, I., 108.9-10) but
it is doubtful whether the Rig Veda knew or guessed exactly the limit or the vertical height of
the atmosphere, from these verses:
;fnUnzkXuh ijHkL;ka i`fFkO;ka e/;eL;keoeL;keqr LFk%A
vr% ifj o`’k.kkok fg ;kraeFkk lkseL; fiora lqrL;AA R.V. I,108.9-10 AA
‘kM~ Hkkjksa ,dks vpjfUoHkR;Zra if’kZ’Beqi xko vkxq%A
frL=ks eghLijkLrLFkqjR;kxqgk }s fufgrs n”;sZdkAA R.V. III, 56.2 AA
=h ‘k/kLFkk flU/kokfL=% dohukeqr f=ekrkfon;s’kq lezkVA
_rkojh;ksZ’k.kkfLrL=ksZ vI;kfL=jk fnoks fon;s izR;ekuk%AA R.V.,III,56.5AA
f=[rfj{ka lfork efgRouk =h jatkfl ifjHkwL=hf.k jkspukA
frL=ks fno% ifFkohfLrL= bUofr f=fHkczrSjfHk uks j{kfr ReukA R.V.,IV,53.5 AA
We read “Savitr (the Sun) encompassing them by magnitude pervades the three divisions of the
firmament, the three world, the three brilliant spheres, the three heavens, the three-fold Earth. In
57
this connection a very significant question comes in to mind whether the three divisions of
firmament denote troposphere, stratosphere, and ionosphere? Again in the triple divisions of the
earth are we entitled to identify frigid, temperate and torrid zones, for different schools regarding
Aryan home do recognize the Rig Vedic Aryans’ knowledge about frigid and temperate zones
and, it is just possible that in course of their ocean voyages and advances for habitat, they might
have known torrid zone also.
The Vedic people were well aware that plants (or forests) had some influence on the loss of water
and causation of rainfall (TS., II,4.9.3).
lkSHk;;SokgqR;k fnoks o`’Veo #U/ks e?kq’kk la ;kSR;kika ok ,’k vks’k/khuka
jlks ;Ue/oHkn; ,okS’k/khHk;ks o’lZR;Fkks mn~Hk; ,okS’k/khHk;ks o`f’Va fu u;frAA TS.,II,4.9.3 AA
The concept and role of insolation is also referred to in the Taithiriya Samhita. Agni (Insolation)
causes the rain to arise (T.S., II,4.10.2) as:
vgksjk=kHk;ka itZU;a o’kZ;rks Xus;s /kkePNns iqjksMk”ke’Vkdikya fuoZ;sUek#ra
lIrdikylkS;ZesddikyefXuokZ brks o`’V eqnhj;fr e#r% l`’Vka u;fUr ;nk [kyq
ok vlkokfnR;ks U;M- jf’efHk% I;kZorZrsFk o’kZfr /kkeNfnfo [kyq oS HkwRok
o’kZR;srk oS nsork o`’V;k bZ”krs rk ,oa Losu Hkkx/ks;suksi /kkofr rkAA TS.II,4.10.2 AA
The epic Ramayana also furnishes a lot of information regarding the atmosphere, its conditions
and cosmic regions, up to the distance of the Moon from the Earth. Entire atmospheric cosmic
stretch was divided into nine regions, where last one is the longest. Ramayana (I.47.4) describes
mythically the origin of the atmospheric regions.
okrLdU/kk bes lIr pjaUrq fnfo iqpdA
ek#rk bfr fo[;krk fnO;#ik ekekRetk%AA Ramayana.I,47.4 AA
Intensive insolation and high temperature work as an agency of destruction or dispersion of the
existing clouds is spoken of in VI.43.29 of Ramayana as:
fufoZHksn “kjSLrh{.kS% djSesZ?kfeoka”kqeku~AA Ramayana.VI,43-29 AA
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In the Ramayana, we read about evaporation by the Sun’s rays in general verse (II.105.20), and
about the formation of clouds due to solar heating of the ocean (VII,32.68) as:
vk;wf’kZ {ki;UR;k”kq xzh’es tfyeoka”ko%AA Ramayana,II,105.20 AA
mn~Hkwr vkrikik;s I;ksnkukfeokEcq/kkSAA Ramayana,VII,32.68 AA
The insolational heating of the ocean water is also referred to in the Verse VII.25.30 of
Ramayana.
nkSnkRE;sukReuks}rLrkIrkEHkk bo lkxj%A
rrks czohn n”kxzho% dqnz% lajDrykspu%AA Ramayana.VII,25.30 AA
In the twelfth skanda of epic Mahabharata, the atmosphere is divided into seven regions (Skanda,
Spheres) and they are discussed in considerable detail. The wind named as vkog (M.B.XII,
328.37), blows with a loud noise. Another wind which drinks up water from the four ocean and
having sucked it up gives it to the clouds in the sky and subsequently to rain god is called m}g
(MB. XII, 328.38-39) as:
vEcjs LusgeHk;sR; fo/kqnk Hk;”p egk/kqfr%A
vkogks uke laokfr f}rh;% “oluks unuAA MB.XII,328.37 AA
mn;a T;ksfr’kka “k”or lkseknhuka djksfr ;%A
vUrnsZgs’kq pksnkuka ;a onfUr euhf’k.k%AA MB.XII,328.38 AA
;”prqE;Z leqnzsHk;ks ok;q/kkZj;rs tye~A
m)R;knnrs pkiks thHkwrsHk;ksEcjs fuy%AA MB.XII,328.39 AA
Apart from the wind, the sun was realized as the main cause of evapotranspiration. The Vana
Parva tells us that the Sun evaporates moisture from all plants and water bodies and causes
rainfall (MB.III.3.49). The epic informs us of various types of clouds and atmospheric layers as
well.
Roeknk;ka”kqfeLrstks funk?kksZ loZnsfgukeA
lokS’kkf/kjlkuka p iquoZ’kkZlq eqTpflAA MB.III.3.49 AA
langR;Sdk.kZoa loZ Roa “kks’k;fl jf”efHk%AA MB.III.3.59 AA
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Kanada in his Vaisesika Sutra (Vais. Sutra., 5.2.5) explains the cause of evaporation of water
thus, “the Sun’s rays cause the ascent of water, through conjunction with air”:
ukb;ks ok;q la;ksxknkjksg.kae~AA Vais.Sutr.5.2.5 AA
Kanada was also acquainted with convection currents in the atmosphere which he refers to in
very scientific terms as:
uksnukihMukRla;qDr la;ksxkPpAA Vais.Sutr.5.2.6 AA
Author and commentator Sankara Misra (1600 AD) has beautifully explained this and illustrated
it with the example of a kettle of water heated from below (Tripathi,1969). It conclusively proves
that the great philosopher Kanada knew that the Earth is heated by sun’s rays through radiation
and convection currents in the atmosphere.
Various Puranas inform us that there are seven regions or layers ¼okrLdU/k½ in the atmosphere or
there are seven types of winds (Vayu. 49.163). Narada Purana speaks of seven air channels
(60.13) viz. lIrSrsok;qekxkZ%] Kurma Chapt. 41.6-7 also reveals same thing with little variations as
described here:
jlkryrykRlIr lIrSok/oZryk% f{krkSA
lIr LdU/kkLrFkk ok;ks% lczg~elnuk f}tk%AA Vayu.49.163 AA
vkog% izog”pSr rrSokuqog% iqu%A
lEcgks foog”pSo rnwn~/oZ L;kRijkog%AA Kurma.41.6 AA
rFkk ifjog”pSo ok;ksosZ lIr use;%AA Kurma. 41.7 AA
The phenomena of evaporation, cloud formation and their relationship with winds or regions of
atmosphere ¼okrLdU/k½ are quite satisfactorily described in several Puranas (Brahamand Vol. II,
Chapt. 9., Vayu. Chapt. 51, Linga, I,41, Matsya, I,54) and a full-fledged separate chapter has
been devoted to them in these topics, which positively evinces that due importance of this branch
of meteorology was realized. Some of the verses are quoted here as:
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uko’V;k ifjfo”esr okfj.kk nhI;rs jfo%A
rLekn;% ficU;ks oS nhI;rs jfojacjsAA Brahmand, Vol.II,9.138 AA
rL; rs j”e;% lIr ficaR;aHkks egk.kZokrA
rsukgkjs.k lanhIrk% lw;kZ% lIr HkoaR;qrAA Brahmand,Vol.II,9.139 AA
o’kkZ?keksZ fgea jkf=% la/;k pSo fnua rFkkA
“kqHkk”kqHka iztkuka p /kqzokRloZ izorZrsAA Vayu. 51.11 AA
/kqzos.kkf/kdrka”pSo lw;ksZikoR; fr’Bfr%A
rns’knhIr fdj.k% l dkyhfXufnZokdj%AA Vayu. 51.12 AA
lw;Z% fdj.ktkysu ok;qeqDrsu loZ”k%A
txrks tyeknRrs d`RLuL; f}t lRrek%AA Vayu. 51.13 AA
Above lines of Vayu Purana explain that the sun rays along with the air, extract water from earth.
The Linga Purana (I,41.11,21 and 30), specifically recognizes the roll of sun rays in evaporation
of water, which gets converted to clouds and subsequent rainfall.
oSNqrks tkBj% lkSjkokfjxHkkZL=;ksfu;%AA Linga. I,41.11 AA
;k”pklkS rius lw;Z% fioUuHkks xHkfLFkfHk%A
ikfFkZokfXufofHkJkslkS fnR;% “kqfpfjfr Le`rAA Linga. I,41.11 AA
olars pSo xzh’es p “kuS% l rirs f=fHk%A
o’kkZLoFkks “kjfn p prqfHkZL;a izo’kZfrAA Linga. I,41.30 AA
/kqzos.kkf/k’Vrk”pki% lw;ksZ oS xqg; fr’BfrA
loZHkwr”kjhjs’kq Rokiks g;kuq”prkf”p;k%AA Matsya. I,54.29 AA
rstksfHk% loZyksdsHk; vknRrs jf”efHktZyeAA Matsya. I,54.31 AA
leqnzk}k;qla;ksxkr ogUR;kiks xHkLr;%A
rrLRo`rqo”kkRdkysifjorZu fnokdj%AA Matsya. I, 54.321 AA
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The celebrated Jain treatise ‘Surya Prajnapti’ has dwelt upon at length on insolation, radiation
and reflection of the sun’s light and energy and heating of the earth and various surfaces. Its
conception of a contribution to “albedo” appears to be something wonderful, when we take into
account the fact that the work was composed at least nearly half a millennium B.C. The concept
of albedo is an important aspect of modern hydro-meteorology. The evapotranspiration process
is greatly affected by the albedo.
In Prabhrta 4, Sutra 25, detailed discussions are there dealing with insolation or heat of the Sun
¼rki{ks=½] Prabhrta 5, Sutra 26 (designated as ys[kk izfrgfr] reflection of sun’s light), presents a
detailed discussion on the phenomena of scattering of sun’s light, radiation, insolation, reflection
and albedo and gives accurate scientific details. First, it mentions twenty theories on reflection
of the sun’s light held by the adherents of other sects ¼ijrhfFkZdkuke½- Then, it refers to another
important fact that unseen (invisible) objects also posses reflective capacity.
In aphorism, 30 of the 9 Prabhrta, discusses about the nature of convection and radiation heating
through the sun’s ray with reference to earth surface, water bodies and its objects and atmosphere
and its continents. The author of the Surya Prajanapti also speaks that slanting rays of the sun
give lesser heat and vertical ones greater heat. This is discussed with reference to the rising of
the sun, noon and evening and different places (or latitudes). This shows that during Jain period,
the Indians were well known about the heat exchange processes with in-depth technical theories.
Epilogue
The various references and discussions presented in the chapter show the ancient Indians had
developed significant understanding about the processes of interception, and infiltration. The
interception of water by vegetation and hanging of water particles near the surface of Earth on
other materials was also observed, which disappear through the activities of wind and heat. The
modern soil science tells us that the soil is composed of interconnected pore spaces. This was
clearly realized by the ancient Indians and was compared with the veins in the human body,
through which infiltration takes place, which is the source of ground water. Ancient Indians also
developed a very scientific knowledge about evaporation and transpiration. That sun rays, wind,
humidity, vegetation etc. are the major causes of evapotranspiration, was known to them. The
ancient Indians had realized the importance of evapotranspiration as an important facet of water
cycle, energy circulation and food production and, for maintaining the natural eco-system. Solar
phenomena, lightening, wind, cloud formation etc. take place in lower layer of the atmosphere.
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Atmosphere was divided in troposphere, stratosphere and ionosphere and globe in torrid,
temperate and frigid zones which is comparable to modern meteorology. Plants drink up water
through roots which is facilitated by the conjunction of air is alluded to in Mahabharata which
fully corroborates the modern concept of capillarity in soil, water and plant relationship. The fact
that plants and forests have some influence on water loss, differential rate of heating of the
continents and water bodies, formation of convection currents and their effects were well
understood. However, it is point of further research in the ancient hydrologic literature whether
there were specific instruments/techniques to quantify the processes of interception, infiltration
and evapo-transpiration?
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Rivers are invaluable not only for humans but to all forms of life. Not only are rivers a great
place for people, but people use river water for drinking-water supplies and irrigation, to produce
electricity, to transport merchandise and to obtain food. Rivers are major aquatic landscapes for
all manners of plants and animals. Rivers even help keep the aquifers underground full of water
by discharging water downward through their stream beds.
The knowledge about stream flow is an essential requirement for construction of hydraulic
structures such as dams. The first major human settlements in the Indus Valley (3000-1500 B.C.);
called Indus civilization or Harrapan civilization, demonstrated a high degree of hydraulic
engineering skills (Pandey, 2016). After the Harappan culture came to its abrupt end, the Vedic
age was started. According to the Vedic knowledge, all life on this planet evolved from Apah
(water). Literary references and archaeological data from about 6th century BC onwards indicate
the development of embankments, canals and other hydraulic works. Literature suggests that
there were a large number of hydraulic structures built (dams, canals and lakes) during the
Mauryan period in Indo-Gangetic plains and other parts of the country for irrigation and drinking
purposes (Shaw et al., 2007; Sutcliffe et al., 2011). Surprisingly, many of these structures were
equipped with the spillways to consider the flood protection measures. This chapter briefly
discusses about the ancient knowledge in the field of geo-morphology and surface water
hydrology as available in the Vedas and other ancient literature.
The Rig Vedic hymns X.B2.1 and X.121.1 state that the creation had started with the origin of
water and the cosmic golden egg (embryo) ¼fgj.;xHkZ½ which very well fits in the geological and
biological evolution of the earth with the water age, origin of zoophytes, primeval fishes, reptiles,
invertebrates, vertebrates and mammals.
p{kq’k% firk eulk fg /khjk s ?k`resus vtuUuEuekusA
;nsnUrk vnn`gUr iwoZ vkfnnn;kokifFkoh vizFksrke~AA R.V.X, 82.1 AA
fgj.;xHkZ% leorZrkxzs HkwrL; tkr% ifrjdsZ vklhr~A
l nk/kkj ifFkoh ?kkeqrseka dLes nsok; gfo’kk fo/kse~AA R.V.X,121.1 AA
Chapter-5
GEOMORPHOLOGY AND SURFACE WATER
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According to the Rig Veda, the earth abounds in heights, bears the burden of mountains and
supports the trees of the forests in the ground ¼{kek½- She quickens for she scatters rain, and the
showers of heaven are shed from the lightning of its clouds. The Earth is great ¼egh½] firm ¼n`<+½
and shining ¼vtqZuh½-
Perhaps the Rig Vedic Aryans had the concept of knowing slopes also of a region with the help
of rivers as indicated (R.V.IX, 88.6) below:
,rs lksek vfr okjk.;O;k fnO;k u dks”kklks vHkzo’kkZ%A
o`Fkk leqnza flU/koks u uhph% lqrklks vfHk dy”kka vl`xzuAA R.V.IV, 88.6 AA
Talking about the river flow whose turbulence is lost after meeting the oceans, the Rig Veda
says:
leU;k ;UR;q; ;UR;U;k% lekuewoZ u?k% i`.kkUrAA R.V.II, 35.3 AA
In the verses IV,18.6 and IV,19.3 of the Rig Veda, it is said that the rivers are the daughters of
sun and cloud. They run towards oceans breaking the soil, rocks etc. coming on their way. They
flow in through zig-zap paths:
,rk v’kZUR;ykykHkoUrh_rkojhfjo laØks”kekuk%A
,rk fo iqPN fdfena HkrfUr dekiks vfnzafifjf/ka #tkfUrAA R.V.IV, 18.6 AA
During the Rig Veda period, Aryans were probably acquainted with the river velocity at different
stages. One verse (VI 24.6) mentions the high speed of mountainous rivers flowing down the
slope as:
fo RonkikS ioZrL; i`’BknqDFksfHkfjUnzku;Ur ;KS%AA R.V.VI, 24.6 AA
By the time of Sam Veda, Yajur Veda and Atharv Veda, the Indians had come to acquire
sufficient knowledge of physiography and geomorphology. This is established by the
geographical technical terms – mig~oj (mountain slopes, SV.II, 5.9), bfj.k (cleft or Åij½] f”kyk
(stony place), {k;.k (habitable place), dkV (forest having a difficult communication), gn~ (lake),
yksi (rugged lands or bad lands) (TS,IV,5.9.1). In the Sam Veda, we come across a brief but fine
65
description of a river mouth and a wave of the sea opposite to the mouth of a river sends into it
a portion of its water (SV XIV, 4). The prithvi sukta (XII) of the Atharv Veda, furnishes a concise
account of physiography – mountains, snowcapped mountains, forest lands, plain areas ¼le½ and
perennial stream or slopes ¼izor½- Following hymn of Atharv Veda illustrates that if the water
source is on mountains, then the river formed will be perennial and will flow with high speed
(AV.I.,15.3) as:
;s unhuka laL=oUR;qRlkl%A A.V.I.,15.3 AA
Similarly, verse II, 3.1 of the Atharv Veda reveals the same fact saying that the rivers originating
from snowclad mountains will keep on flowing in summer also.
vnks ;no/kkoR;oRdekf/k ioZrkr~AA A.V.II,3.1 AA
In the Gopatha Brahmana, the nomenclature for a meandering river is foikV (II.8). It was also
acquainted with two types of springs or falls, namely hot and cold (“khrks’.kkfogksRlkS, G.B.II,8). The
celebrated epic Ramayana also reveals very rich and accurate knowledge of various types of
geomorphological patterns. Some of the geomorphological patterns as mentioned in the
Ramayana related to water are rivers and rills and plateaus, caverns and fountains (II,54.42.) the
plain tracts (II,56.11), sandy banks of rivers (Rama. II,55.31):
lfjRizL=o.kLFkku~ njhdUnjfu>Zjku~AA Rama. II, 54.42 AA
leHkwferys jE;s nqzeScZgqfHkjkorsA iq.;s jaL;kegs rkr fp=dwVL; dkuusAA Rama.II.56.11 AA
fofp=okyqdtyka gallkjlukfnuke~A
jsestudjktL; lqrk izs{; rnk unhZe~AA Rama. II,55.31 AA
Those lands watered by the Ganga have been described as dense and hard to track (Rama. II,85.4)
as:
drjs.k xfe’;kfe Hkj}ktkJea ;FkkA
xgkuks;a Hk`”ka ns”kks xM~xkuwiks nqjR;;%AA Rama. II,85.4 AA
Knowledge of water falls (II,94.13) and descent of a river (II,103.25) is described as below:
66
tyizikrS#nHksnSfuZ’iUnS”p Odfpr~A
L=ofnHkHkZR;;a “kSy% L=oUen bo f}i%AA Rama. II,94.13 AA
unhZ eUnkfduh jE;ka lnk iqf’irdkuuke~AA Rama. II,103.24 AA
“kh?kz L=ksrleklk?k rhFkZ f”koednZee~A
flf’kpqLrwnda jkts rr ,rn~ HkofRofrAA Rama.II,103.25 AA
How after melting of snow, a mountainous topography becomes charming is spoken of thus –
fgekR;;s uxfeo pk#dUnje~ (Ramayana II, 7.15). The author of the epic has also marked “river
erosion on non-resistant or soft steep river bank (II,63.46; V,34.19; VII,14.18) as:
#.kf} e`nq lksRls/ka rhjeEcqj;ks ;Fkk AA Rama.II,63.46 AA
fpRra gjfl es lkSE; unhdwya ;Fkk j;%AA Rama.,V,34.19 AA
lhnfUr p rnk ;{kk% dwyk bo tysu gAA Rama.,VII,14.18 AA
In the verse VII, 23.42 of the Ramayana, we read about the erosive action of the downpour of
rain on mountains. viz.
lk;dS”pkiodHkz’VSoZtzdy~iS% lqnk#.kS%A
nkj;fUr Le ladq}kes?kk bo egkfxfje~AA Rama., VII, 23.42 AA
The Mahabharata divides the Himalayan mountains into three regions. It mentions large tracts
of desert several times (I, 70.2). In certain context the word unhdPN is used. Most probably it
indicates the land form which now-a-days is called delta.
,d ,oksRreoy% {kqfRiiklkJekfUor%A
l ouL;kUreklk?k egPNwU;a leklnr~AA M.B.,I,70.2 AA
unhdPNksn~Hkoa dkUreqPNr/ot lafuHkeAA M.B.,I,70.17 AA
In Panini’s Astadhyayi (600-700 BC), we come across several important geomorphological
patterns. The grammarian calls a river moving and breaking its banks as fHkU?k and that whose
water overflows the banks as mn~/; (III,1.15). Glacier is named fgekuh (IV,1.49) as:
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bUnzo#.kHko”koZ#n~eM+fgekj.;;o;ouekrqykpk;kZ.kekuqdAA Astadhya.,IV,1.49 AA
Topography and geomorphology have been discussed very well in the Arthasastra by Kautilya
(4th century BC) during the Mauryan period. Various types of lands such as “forests, villages,
waterfalls, level plains and uneven ground”, stretching between the Himalayas and ocean
(Arthasastra, Trans. by Shamshastri P.404) have been mentioned there. At various places he
speaks of fertile, infertile, cultivable, uncultivable and waste land, which reveals that he must
have possessed good knowledge of the science of soil also at that time.
The Vayu Purana refers to various types of topography namely lakes, dales, barren tracks
(Chapter 38), rocky through between mountains ¼vUrnzks.kh½ (38.36).
if”pek;ka fnf”k rFkk ;sUrjnzksf.kfoLrjk%A
rkUo.;ZekukaLrRosu J`.kqrsekfU}tksRrek%AA Vayu.,38.36 AA
The chapter 38 of Vayu Purana also speaks about the large number of hot springs in a
mountainous region (38.78).
rFkk g;uyrIrkfu ljkafl f}tlRrek%A
“kSydq{;UrjLFkkfu lgL=kf.k “krkfu pAA Vayu.,38.78 AA
In the Markandeya Purana (53.21-22), we come across a peculiar type of topography found “in
the Kimpurusaversa and seven other countries” where water bubbles up from the ground as:
uoLofi p o’ksZ’kq lIr lIrdqykpyk%A
,dsdfL=Lr Fkk ns”ks u?k”pkfnz fofu% lrk%AA Markandeya P.53.21 AA
;kfu fda iq#’kk?kkfu o’kkZ.;’VkS f}tksRre%A
rs’kwfnHkTtkfu rks;kfu uSoa ok;Z= HkkjrsAA Markandeya P.53.22 AA
The Vishnu Purana (II,5.3) classifies the soils of sub-terranean region in seven categories viz.
(1) black, (2) white or yellowish, (3) blue or red, (4) yellow, (5) gravelly, (6) hilly or boulder and
(7) golden hued, as:
“kqDyd`’.kk% ihrk% “kdZjk% “kSydkTouk%A
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Hkqe;ks ;= eS=s; ojizklknekf.MrkAA Vishnu.,II,5.3 AA
The Vrhatsetrasamsa (6-7 century AD) (Tripathi, 1969) has many scientific and mathematical
enumerations conforming to some hydrographical or hydrological laws. Anguttaranikaya (before
400 B.C.) classifies lakes into four categories (part II, page 105, Tripathi, 1969).
Epilogue
From the above discussions, we see that in ancient India, the knowledge of streamflow and
geomorphology was well developed on scientific lines. A number of hydraulic structures were
constructed during that time for irrigation and domestic purposes. The techniques of knowing
slope of an area by means of a flowing river and dimensions of river at various stages along with
velocity were developed. That the mountainous rivers are generally perennial and deposition of
fertile soil takes place periodically on flood plains was understood which is in accordance to the
modern experiences. The arrangement of sluice gates was also made in the dams for flood
protection purposes. Various types of topographies such as springs, water falls, mountainous,
plateau, eroded land etc. along with many geographical terms such as f”kyk] bfj.k] {k;.k] yksi were
used. Land classification such as fertile, infertile, cultivable, waste land etc. and soil
classifications, such as black, yellow, red, gravelly, boulders etc. was well in vogue before 4th
century B.C. These are in vogue even at present and hence, can be regarded as the important
achievement of the ancient Indians in this field.
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Groundwater development and utilization has been of great interest from ancient times in arid
and semi arid regions of Asia where the activities of man were controlled by the occurrence of
water. From the dawn of history until comparatively recent times the source of water of the
springs and streams had constituted a puzzling problem and had been the subject of much
speculation and controversy. Mohenjo-Daro was a major urban center of the Indus civilization
during the early Bronze Age (around 2450 BC). Recently, Angelakis and Zheng (2015) found
that the city was receiving water from at least 700 wells. The design of these wells was varying
from circular to pipal leaf shaped (Khan, 2014). Figure 6.1 shows the wells constructed in about
2600 BC, discovered at Lothal, an important Harappan site.
Figure 6.1: Wells discovered at Lothal, 2600 BC
(Source: https://rainwaterharvesting.files.wordpress.com)
The ancient western science of groundwater, which generally assumed that the water discharged
by the springs could not be derived from the rainfall, was based on their belief that: (i) the rainfall
was inadequate in quantity and (ii) the earth was too impervious to permit penetration of the
rainwater far below the surface. In contrast to above wild theories, the ancient Indian literature
contains the very valuable and advanced scientific discourse on ground water.
In Rig Veda, Sam Veda and Yajur Veda we get concepts of hydrological cycle and water use
through wells etc., which clearly imply the use of groundwater. In the area of groundwater
renowned astronomer, astrologer and mathematician, Varahmihira (AD. 505-587), author of
Chapter-6
GROUND WATER
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Vrhat Samhita, which is esteemed for its learning of many important branches of knowledge, in
the 54th chapter entitled ‘Dakargalam’, deals with ground water exploration and exploitation with
various surface features, that are used as hydrologic indicators to locate sources of ground water,
at depths varying from 2.29 m to as much as 171.45 m (Prasad, 1980). The hydrologic indicators,
described in this ancient Sanskrit work, include various plant species, their morphologic and
physiographic features, termite mounds, geophysical characteristics, soils and rocks. All these
indicators are nothing but the conspicuous responses to biological and geological materials in a
microenvironment, consequential to high relative humidity in a ground water ecosystem,
developed in an arid or semi arid region. Variation in the height of water table with place, hot
and cold springs, groundwater utilization by means of wells, well construction methods and
equipment are fully described in the Dakargalam (Jain et al., 2007).
The treatise on Dakargalam (science of underground water) by Manu is referred to in the Vrhat
Samhita. By the latest his time must be (400BC-200BC). Varahmihira alludes that euquk fojfpra
ndkxZye which clearly indicates Manu’s contribution to this science. This also indicates that the
science was cultivated in India several centuries before Christ and that it was developed by
indigenous people altogether independently. Varahmihira has utilized to a greater extent another
treatise on the science of underground water and water table, written by ‘Saraswat’. Rather the
farmer (Manu) appears to give a preference to the latter over the Manava Dakargalam (Vrhat
Samhita, 54.99).
lkjLorsu eqfuuk ndkxZya ;r~ dra ryoyksD;A
vk;kZfHk% dresrn~o`RrSjfi ekuoa o{;sAAVr.S.54.99 AA
As far as underground water and water table is concerned as a science, a brief survey of chapter
54 of the Vrhat Samhita designated as ‘Dakargalam’ is furnished below. Apart from the wider
term ‘Dakargala’, there are two other technical terms f”kjk and f”kjkfoKku used in this chapter
(Verse 54.1, 54.61-62) viz.
/kE;Z ;”kaL;a p onkE;rksga ndkxZya ;su tyksiyfC/k%A
iqalka ;FkkXMs +’kq f”kjkLrFkSo f{krkofi izksUurfuEu laLFkkAA Vr.S.54.1 AA
e#ns”ks Hkofr f”kjk ;Fkk rFkkr% ija izo{;kfeA
xzho djHkk.kkfeo HkwrylaLFkk% f”kjk ;kfUrAA Vr.S.54.62 AA
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The term f”kjk implies arteries of water or streams and the f”kjkfoKku exactly conveys the meaning
of water table. Verse 54.1 above tells us that at some places water table is higher and at others it
is lower, resembling the veins in the human body. From Verse 54.2 we learn that water table is
a complex function of rainwater.
,dsu o.ksZu jlsu pkEHk”P;qra uHkLrks olq/kkfo”ks’kkrA
uukjlRoa cgqo.kZrka ,oa ijh{;a f{kfrrqy~;esoAA Vr.S.54.2 AA
It means, the water which falls from the sky originally has the same colour and same taste, but
assumes different colour and taste after coming down on the surface of the earth and after
percolation. Figure 6.2 shows infiltration and percolation process for an unconfined aquifer
leading to different zones of groundwater.
Figure 6.2: Unconfined aquifer showing different zones: uppermost soil moisture where
precipitation infiltrates downward to the water table where all the open
pore spaces are filled or saturated (Source: UNO, International programs)
In the later verses of Dakargalam, the modes of occurrence of sub-terrainian water and its depth
at different places are given. Verse 54.3, 54.4 and 54.55 inform us that the sub-terrainian streams
are rainfed in all the quarters and also apart from nine arteries, thousands more are present
flowing to various directions as:
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iq#gwrkuy;efu_fro:.kiousUnq”kadjk nsok%A
foKrO;k% Øe”k% izkP;k?kkuka fn”kka ir;%AA VR.S.54.3 AA
fnDifrjkTKk p f”kjk uoeh e/;s egkf”k”kukEchA
,rkHk;ksR;k% “kr”kks fofu% l`rk ukefe% izfFkrk%AA Vr.S.54.4 AA
ikrkykVw/okZf”kjk “kqHkk prqfnZ{kq lafLFkrrk ;k”pA
dks.kfnxqRFkk u “kqHkk% f”kjkfufeRrkU;rks o{;sAA Vr.S.54.5 AA
Rock or soil structure and depth of water table from the surface of the earth is described correctly
in various verses. Verse 54.7 describes the various symptoms of occurrence of water along with
pervious and impervious strata.
fpUgefi pk/kZiq#’ks e.Mwd% ik.Mqjks”k e`r ihrkA
iqVHksnd”p rLeu~ ik’kk.kks Hkofr rks;e/k%AA Vr.S.54.7 AA
Meaning: on digging we will get yellow frog at a depth of half purusha (1 purusha = height of
man with erected hand = 7.5 feet) then yellow soil, then rock and then ample amount of water.
Similarly, many other verses describe some 70 odd field situations or ecological spectra from
which it would be possible to deduce the presence of underground springs. Actually the
technique of underground water exploration as described by Varahmihira depends upon a close
observation of naturally occurring specific signs in the terrain, comprising the flora, fauna, rocks,
soils and minerals, whose state and variation can be logically or empirically linked up with the
presence of underground springs in the vicinity.
One startling factor emphasized in details by Varahamihira is the role of termite knolls as
indicator of underground water. Apart from the underground water exploration, some of the
verses of the chapter deal with topics such as digging of wells, their alignment with reference to
the prevailing winds, dealing with hard refractory stony strata, sharpening and tempering of
stone-breaking chisels and their heat treatment, treating with herbs of water with objectionable
taste, smell, protection of banks with timbering and stoning and planting with trees, and such
other related matters.
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Some thirty-three verses of the Varahsanhita deal with termite, standing alone by themselves or
associated with vegetation, thirty with vegetational factors alone and the remaining using other
factors to help in exploration.
tEcwo`{kL; izkXoy~ehdks ;fn Hkosr lehiLFk%A
rLeknnf{kiik”osZ lfyya iq#’k}s; LoknqAA Vr.S.54.9 AA
mnxtqZuL; n`”;ks cy~ehdks ;fn rrkstqZuk}LrS%A
f=fHkjEcq Hkofr iq#’kSL=fHkj/kZlefUorS% i”pkrAA Vr.S.54.12 AA
Meaning: If there is a termite mound nearby to the east of a Jambu tree, plenty of sweet water,
yielding for a longtime occurs at a depth of two purushas, at a distance of three hastas (cubit) to
the south of the tree (54.9). Similarly, an Arjuna tree with a termite mound to the north shows
water at a depth of 3.5 purushas at a distance of 3 hastas to the west.
The mound builder variety of the termites are responsible for the impressive soil structure called
‘Ant-hills’ in lay terms, but referred to as termite – knolls – mounds – spires, or – prominences
by the scientists. These are familiar features of most tropical and subtropical landscape and are
of interest to us in the technique of exploration of underground springs. Without exception, the
water requirements of the insects are generally very high and they need to protect themselves
against fatal desiccation by living and working within the climatically sealed environment of
their nest or within earth-covered galleries. According to Rao et al. (1971) the atmosphere within
the nest has to be maintained practically at saturation moisture level (99-100% relative
humidity). It is a matter of common observation that whenever a termite nest or runway is
damaged, the insects immediately rush to the breach and repair it with wet soil brought up from
within the nest. From an overall consideration of the evidence it seems to be safe to conclude
that, while normally the insects use every readily available near a source of water close to the
ground surface, under conditions of severe climatic stress, they can and probably do descend to
the water table, no matter how deep it may be. Hence, a well-developed, active, persistent colony
of mould-building termites can be taken as an indication of underground springs in the proximity.
E.G.K. Rao (1979) observed the alignment of the termite knolls in the dry-jungle uplands of
coastal Mysore as well as the Deccan Plateau area, and testified the verses of Vrhat Samhita
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relating the same. Following verse of Vrhat Samhita suggests that the author was aware of this
tendency of mould builders.
cy~ehdkuka iDM+R;ka ;?ksdksHk;qPNr% f”kjk rn/k%AA Vr.S.54.95 AA
Meaning: If in a line of termite-moulds one is found to be raised up (taller), water vein is to be
found within it.
Similarly, Verse 82 says that if a group of five termites are found in a place, and the middle one
among them is found white, water should be declared in it at a depth of fifty five purushas (i.e.
7.5’ X 55 = 412.5 feet).
It is a matter of common observation that many times territories are met with in close association
with trees; and it is quite common sight to see termite mounds completely covered over with
grass or vegetation. Very close observation is often necessary to detect the termitary. The ancient
Indian scholar has exploited this association quite extensively in the exploration of underground
springs as discussed below:
tEcwfL=o`rk ekSohZ f”k”kqekjh lkfjok f”kok “;kekA
oh#/k;ks okjkgh T;ksfr’erh x:.kosxk pAA Vr.S.54.87 AA
lwdfjdek’ki.khZO;k/kzink”psfr ;?kgsfuZy;sA
oy~ehdknqRRjrkRL=hfHk% djSfRL=iq:’ks rks;eAA Vr.S.54.88 AA
Meaning: If Jambu, Trivrt, Maurva, Sisumari, Sariva, Siva, Syama, Varahi, Jyotismati,
Garudavega, Sukarika, Masaparni, Vyaghra Pada trees and creepers are seen by a termite mound,
there is water 3 hastas to its north at a depth of 3 purushas”.
The botanical names of the flora mentioned in the above verses are: Jambu (Eugenia Jambos,
Engenia Jambolana), Trivrta (Ipomea turpethum), Maurvi (Sanservieraroxburgiana), Sisumari
(?), Sariva (Hemidesmus indicus), Siva (Several Plants: Cucumis Utilissimus, Terminalia
Chebula, Emblica officinalis, Cynodon dactylon), Syama (Ichnocarpus fructens – black creeper,
Krsna Sariva, Datura metal, Agalala rox-burgiana, Panicum coloncum etc.), Sukarika
(Lyccopodium imbricatum, I. Clovatum), Masaparni (Glycine debitis, G. Labialis).
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Similarly, various other verses of the chapter 54 of Vraht Samhita are related to the underground
water exploration with relation to combination of different symptoms, as below:
vr`.ks ln`.kk ;l~feu lr`.ks r`.koftZfLerk egh;=A
rfLeu~ f”kjk izfn’Vk oDrO;a ok /kua okfL;uAA Vr.S.54.52 AA
Meaning: if in a grass less place, there is a patch of grass or in a grassy place, there is a grassless
place, water or treasure is indicated.
d.VD;d.Vdkuka O;R;klsEHkkfL=fHk% djS% Ik”pkr~A
[kkRok iq#’kf=r;a f=Hkkx;qDra /kua ok L;kr~A Vr.S.54.53 AA
Meaning: a flourishing thorny tree in the midst of non-thorny trees or vice-versa indicates water
or treasure at a depth of 3 ¾ Purushas at a distance of 3 hastas to the west”.
;L;kew’ek /kk=~;ka /kweks ok r= okfj uj;qxysA
funsZ’VO;k p f”kjk egrk rks;izokgs.kAA Vr.S.54.60 AA
Meaning: where there is stream or smoke issuing from the ground, an abundant water vein will
be struck at a depth of 2 Purushes. Varahamihira has also discussed the occurrence of
underground water in the desert region. He further says that sub-terraineon streams or water table
in the desert region takes the shape of the neck of a camel and is at a great depth from the surface
of the earth as:
e#ns”ks Hkofr f”kjk ;Fkk rFkkr% ija izo{;kfeA
xzhok djHkk.kkfHko HkwrylaLFkk% f”kjk ;kfUrAA Vr.S.54.62 AA
Geological strata scheme of the modern artesian well fully corroborates this.
In the Verse 102 of the Vrhat Samhita , it is described how water occurs in a mountainous region.
foHkhrdks ok en;kfUrdk ok ;=kfLr rfLeu iq#’k=;seHk%A
L;kRiorZL;ksifj ioZrksU;Lr=kfi ewys iq#’k=;sEHk%AA Vr.S.54.102 AA
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l”kdZjk rkezegh d’kk;a {kkja /kfj=h dfiyk djksfrA
vkik.Mqjk;ka yo.ka izfn’Va e`’Va Ik;ks uhyolqU/kjk;ke~AA Vr.S.54.104 AA
Above verse (54.104) explains the relation of soil and water. It says that pebbly and sandy soil of
copper colour makes water astringent. Brown-coloured soil gives rise to alkaline water, yellowish
soil makes water briny and in blue soil underground water becomes pure and fresh.
In Ramayana we come across the knowledge of artesian wells. The verses VI,22.37-38 say that the
water from deep earth comes out by force continuously through the hole created by arrow of Lord
Rama as:
fuikfrr% “kjks ;= otzk”kfuleizHk%AA Rama., VI,22.36 AA
rLekn oz.keq[kkr rks;eqRiikr jlkrykrAA Rama., VI,22.37 AA
l cHkwr rnk dwiks oz.k bR;so foJqr%A
lrra pksfRFkra rks;a leqnzL;so n”;rsAA Rama., VI,22.38 AA
It clearly and very scientifically explains the artesian well flowing continuously with force. The
Vayu Purana also refers to the various underground structures and topography such as lakes,
barren tracts, dales, rocky rift valley between mountains vUn)ks.kh (38.36). The chapter 38 of the
Purana also speaks of a large number of hot springs in a mountainous region.
RkFkk g~;uRo rIrkfu ljakfl f}t lRrek%A
“kSydq{;UrjLFkkfu lgL=kf.k “krkfu pAA Vayu.38.78 AA
The Gopath Brahmna was also acquainted with two types of springs or falls, namely hot and
cold (II,8).
As mentioned in the previous chapter, in Markandeya Purana we come across a peculiar type of
topography found in the Kimpurusavarsa and seven other countries where water bubbles up from
the ground (55.21-22).
uoaLofi p o’ksZ;q lIr lIrdqykpyk%A
#dSdfLeLeLrFkk ns”ks u?k”pkfnz&fofu% lrkAA Markandeya.53.21 AA
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;kfu fdaiq#’kk?kkfu o’kkZ.;’VkS f}tksRreA
rs’kqfnHkTtkfu rks;kfu uSoa ok;Z= HkkjrsAA Markandeya.53.22 AA
The above discussions reveal that chapter 54 of the Vrhat Samhita is a very important treatise on
ground water exploration.
Epilogue:
Discussions and the references presented in the chapter show that there were well developed
scientific concepts of groundwater occurrence, distribution, prospecting and utilization. It is for
this reason that the people of Harappan civilization were able to dig the wells and able to utilize
the groundwater. By means of hydrologic indicators such as physiographic features, termite
mounds, geophysical characteristics, soils, flora, fauna, rocks and minerals etc., the presence of
ground water was detected, which is fully scientific. Termite mounds were used as an important
indicator of the groundwater by the ancient Indians. The presence and variation of these
indicators have been linked up with the availability of underground springs in modern era too.
Modern scientists have also established that the moisture within the mounds is kept practically
at saturation level (99-100%) indicating the presence of underground spring in proximity. Well
before many centuries of Christ, Indians were aware of underground water bearing structures,
change in the direction of flow of ground water, high and low water tables at different places,
hot and cold springs, ground water utilization by means of wells, well construction methods and
equipment, underground water quality and even the artesian well schemes. This high level of
knowledge of groundwater in those ancient times was developed by indigenous people of India
altogether independently.
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Throughout the history, the use of water has reflected various experiences and interpretations of
and values about health, illness and well being. The idea that water reflects a harmony between
the physical, social and ecological environment can already be found in ancient medicine. As
long as 4,000 years ago, the Indians were having the knowledge of purifying the water through
boiling. Latter, Hippocrates was known to use both water filters and boiling to improve water
quality (UNESCO, IHP, 2011). The modern scientists at one time, used to consider rainwater as
pure like distilled water. But later studies revealed that it is not so. The water of precipitation is
characteristically the purest water in the hydrological cycle, but even so it may collect from less
than 1 to several hundred milligrams of dissolved material per litre of water during its fall
through the atmosphere. Rainwater, as it falls to the earth, has ample opportunity to dissolve
gases from the air and may also dissolve particles of dust or other air borne materials. Thus, rain
water becomes a mixed electrolyte containing varying amounts of major and minor cations and
anions. Sodium, potassium, magnesium, calcium, chloride, bicarbonate and sulphate are the
major constituents. Ammonia and various nitrogen compounds are generally present. Dust
particles are added locally in industrial areas, large population centres and desert areas. Among
the land based factors which may be significant in altering the composition of rainwater are the
sulphur emitted by volcanoes, fumaroles, springs, and dust particles. Rainwater close to the
ocean commonly contains from 1.0 milligram per litre to several tens of milligrams per litre of
chloride but the observed concentration generally decreases rapidly in a landward direction.
In Vedas, we get some references to water quality, especially in Atharv Veda. Charaka Samhita,
Susruta Samhita (both of pre or early Buddhist era), and Ashtanga Hrdaya Samhita (9th century
AD) are the repositories of knowledge accumulated on Ayurveda (Science of Life), during the
earlier period. In all these ancient standard texts, discourses on water quality constitute an
important aspect of Ayurveda. Bhavamisra’s Bhava Prakash (16th century AD), which is more
or less a compilation of all the Ayurvedic texts of earlier antiquity, also elaborately deals with
water quality.
Chapter-7
WATER QUALITY AND
WASTE WATER MANAGEMENT
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In the Rig Veda, the verse V,83.4 speaks about the tree plantation, forest conservation and yajna
¼;K½ so as to create pure and healthy environment and good quality of water for well being of
mankind as:
iz okrk ofUr ir;fUr fo|qr mnks’k/khftZgrs fiUors Lo%A
bjk fo”oEHkS Hkqouk; tk;rs ;RitZU;% iFohZ jsrlkofrAA R.V.,V,83.4 AA
Likewise, verse VII, 50.4 of the Rig Veda also reveals the importance of Yajna ¼;K½ in relation
to purification of water. In Yajur Veda (I,12), we read about the contamination due to
combination of substances and about fire as the prime source of purification, by breaking the
substances into minute particles, i.e. yanja, heat and sun rays are the agents to purify the water.
viz.
ifo=s LFkks oS’.kO;kS lforqoZ% izlo mRiqukE;kfPN.k ifo=s.k lw;ZL; jf”efHk%A
nsohjkiks vxzsxqoks vxzs’koks xz bee?k ;Ka u;rkxzs ;Kifra lq/kkrqa ;Kifra nso;qoeAA Y.V.I.12 AA
In Sam Veda (Previous II.187), we read that the Sun rays cause the rain to come in purest form
like white curd as:
bLekLr bUnz i”u;ks ?k`ra nqgr vkf”kjeA
,uke`rL; fiI;q’khAA S.V.P,II.187 AA
A verse of Atharv Veda (V, 22.5) directs to take preventive measures against the diseases caused
by the areas with much grass, high rainfall and bad water quality, viz.
vksdksa vL; ewtoUr vksdksa vL; egko’kk%A
;koTtkrLrDea Lrkokufl cy~fgds’kq U;kspj%AA A.V.V,22.5 AA
In the celebrated epic Mahabharata (XII,184.31 and 224.42), we read about the various qualities
of water according to its taste. Thus, it is clear that during those days efforts were made to specify
the water quality according to its taste.
jlks cgqfo/k% i zksDr _f’kfHk% izkfFk;kRefHk%A
e/kqjks yo.kfLrDr% d’kk;ksEy% dV`LrFkkAA M.B.XII.184.3 AA
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In the Vrhat Samhita, we find many references to water quality in the 54th chapter named
“Dakargala”. Verse 54.2 states that ground water should be investigated in relation to its
environment.
,dsu o.ksZu jlsu pkEHkjP;qra uHkLrks olq/kkfo”ks’kkrA
ukukjlRoa cgqo.kZrka p xra ijh{;a f{kfrrqy~;esoAA Vr.S.54.2 AA
l”kdZjk rkezegh d’kk;a {kkja /kkfj=h dfiyk djksfrA
vkik.Mqjk;ka yo.ka izfn’Va e`’Va I;ks uhyolqU/kjk;keAA Vr.S.54.104 AA
Soil colour has been described as an indicator of water quality in the Vrhat Samhita (54.104). It
says that “pebbly and sandy soil containing copper makes water astringent ¼dlSyk½- Brown-
coloured soil gives rise to alkaline water, pale white soil to salt water and blue coloured soil
makes water pure and sweet”. A water treatment method was also suggested to improve the
quality of drinking water as:
vTtueqLrks”khjS% “kjktdks”kkrdkeydpw.kSa%A
drdQylek;qDrS;ksZx% dwis iznkrO;%AA Vr.S.54.121 AA
dyq’ka dVqda yo.ka fojla lfyya ;fn ok”kqHkxfU/k HkosrA
rnusu HkoR;eya lqjla lqlqxfU/k x.kSjijS”p ;qreAA Vr.S.54.122 AA
The above verses say that a mixture of Anjanam (collyrium, autimony or extract of ammonium),
Musta tubers (Nagarmodha), Usira (Khas), Powder of Rajkosataka (Torayi), and Amalaka
¼vkoyk½] combined with Kataka nuts should be put into a well. If the water is turbid, pungent,
saltish, of bad taste and not of good odour, it will be rendered clear, tasty, aromatic, and with
other good qualities. Thus, Varahamihira at that time presented a simple method for obtaining
potable water from a contaminated source of water. All above plant materials have medicinal
value and are commonly available in almost all parts of India. In ancient medical texts such as
Charaka Samhita, Susruta Samhita and Astangahradaya Samhita (by Vagbhata), collectively
known as Brahattrayi (Great triad), and three other ayurvedic texts Madhavanidanam,
Sarangadhara Samhita and Bhavaprakasha, collectively known as Laghutrayi (small triad), some
references to water quality are available. In Bhava Prakash many parts have been incorporated
from the medical texts of Charaka, Susruta, Vagbhata and the Tantrik texts. The tenth chapter of
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Bhava Prakash with 86 verses named as Vari Vargah deals with different aspects of water. Here
some aspects of water quality are presented as given in above text (10th chapter, Vari Vargah
part) and also analyzed by Prasad (1979). The shloka 2 states the important properties of water
and its usefulness for the living beings, as:
ikuh;a Jeuk”kua Dyegja ewNkZfiiklkgja rUnzkPNfnZfocU/kg}ydja funzkgja riZ.keAA X.2 AA
Meaning: “the water eliminates the fatigue of the body and mind, destroys weakness. It is good
for heart, gives satisfaction, soft, clear, origin of rasas, and destroyer of vomiting, sleeping
tendency and constipation”.
In shloka 3 and 4, the classification and nomenclature of different forms of water have been
given as:
ikuh;a eqfufHk% izksDra fnR;a HkkSefer f}/kkAA X.3 AA
fnO;a prqfoZ/ka izksora /kkjkta djdkHkoeA
rkS’kkja p rFkk gSea rs’kq /kkja xq.kkf/kdeAA X.4 AA
Water which rains from sky is called ‘Divyam’ and when it gets collected on the earth or as
ground water, it is termed as ‘Bhaumam’ by sages. ‘Divyan’ water is divided in four categories:
‘Dharajalam’ falls as continuous shower from sky, ‘Karakabhavam’ when it falls like the pieces
of stones, ‘Tausaram’ is free from the smoke etc. and ‘Haimam’ is caused from the snow of
Himalayas. Among these ‘Dhavajalam’ is better, having full of qualities.
Similarly, shloka 25 gives classification of Terrestrial water (Bhauma Jalam).
HkkSe;Hk;kS fuxfnRoa izFkea f=fo/ka cq/kS%A
tkXMya ijekuwia rr% lk/kj.ka ØekrAA X.25 AA
It means, “the Bhaum Jalam is of three varieties viz. Jangalam, Anupam, and Sudharanam.
Above water divisions are based on the characteristics of the regions which are differentiated
according to their environmental conditions, as:
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vy~iksn dksy~io{k”p fiRrjDrke;kfUor%A
KkRkO;ks tkXMyks ns”kL=R;a tkaxya tyeAA X.26 AA
cgEcqoZgqo{“p okr”ys’eke;kfUor%A
ns”kksuwi bfr [;kr vkuwia rnHkoa tye~AA X.27 AA
feJfpUgLrq ;ks ns”k% lfg lk/kkj.k% Ler%A
rfLeUns”ks ;nqnda rUrq lk/kj.ka Le`reAA X.28 AA
tkXMya lfyya j{ka yo.ka y?kq fiRruqrA
ofUgdRdQgRiF;a fodkju gjrs ogwu~AA X.29 AA
vkuwia ok;ZfHk’;fUn Loknq fLuX/ka /kua xqjA
lk/kj.ka rq e/kqja nhiua “khrya y?kqA
riZ.ka jkspua r`’.kknkgnks’k=;iz.kqrAA X.31 AA
According to the above verses, the country having sparse trees and less water and having bad
effect of causing pitta and vata disorders are the Jangala region and water originated in this region
is termed as Jangala water. The region having plenty of water and abundant trees and able to
cause Vata and Kapha diseases is called Anupam and its water as Anupam water. The regions
having mixed characteristics of above two types is called Sadharanam region, and its water is
called Sadharana Jalam. Jangala water is saltish, soft, eliminates Pitta and Kapha, promotes
digestion, and a good diet in diseases. Anupa water is tasty, oily, viscus, hard, retards digestion,
promotes Kapha and is a creator of other disorders. Sadharana Jalam is sweet, promotes
digestion, soft, cool, pleasant and eliminates tridosa (three diseases). Thus, we see here that in
the study of water, a large number of factors of ecology have also been considered.
Water Quality Standards
In the various reference quoted above, at various places, we come across the words such as fo”kna
(clear, clean, pure, pellucid, etc.), LoPNe~ (clear), funksZ’k (blemishless), dyq’ka (polluted) and fueZyRoa ¼
(unpolluted).
Shlokas 78-81 describe the characteristics of the contaminated water as:
fifPNya d`feya fDyUua i.kZ”kSokyndnZeS%A
foo.kZ fojla lkUnza nqxZU/ka u fgra tyeAA X.78 AA
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dyq’ka NUueEHkksti.kZuhyhr.kkfnfHk%A
nq% Li”kZuelaLi`’V lkSjpkUnzejhfpfHk%AA X.79 AA
vukRrZoa okf’kZda rq izFke rPp~ HkwfexeA
O;kiUu~ ifjgZRrO;a loZnks’kizdksi.keAA X.80 AA
rRdq;kZRLukuikukHk;ka r`’.kk/ekufpjTojkuA
dklkfXueka?kkfHk’;Und.Mwx.Mkfnda rFkkAA X.81 AA
According to these verses “waters which are of sticky nature, containing worms and spoilt by
leaves and mud, of bad colour, thick, of bad smell, are not good for health. Muddy water and
water covered by lotus leaves, grass etc., un-illuminated by sunlight or moonlight, lacking
movement, caused by untimely rain or the first rain water which gets collected in the ground,
such waters are the source of many disorders. Thus, they should be prohibited because the use
of such waters for drinking and bathing purposes, cause r`’kk] vk/;keku] th.kZToj] vXuekUn] d.Mq] x.Mk
and so on. A critical study of other shlokas also clearly reveals the approach of ancient Indians
for water quality standard for different uses.
Variation in the quality of water with seasons, as also from different sources, has been explained
in shlokas 59-67.
gseUrs lkjla rks;a rkM+kxa ok fgra Le`reA
gseUrs fofgra rks;a f”kf”kjsfi iz”kL;rsAA X.59 AA
olUrxzh’e;ks% dkSi okI;a ok fu>Zja tyeA
ukns;a okfj ukns;a olUrxzh’e;kscqZ/kS% fo’ko}uo`{kk.kka i=k?kSnwZf’kra ;r%AA X.60 AA
vkSnfHkan pkUrfj{ka ok dkSia ok izkof’k Lere~A
“kLra “kjfj ukns;a uhjea”kwnda ije~AA X.61 AA
fnok jfodjStqZ’V fuf”k “khrdjka”kqfHk%A
Ks;ea”kwnda uke fLuX/ka nks’k=;kige~AA X.62 AA
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vufHk’;fUn funksZ’kekUrfj{ktyksiee~A
cy~;a jlk;ua es/;a “khra y?kq lq/kklee~AA X.63 AA
“kjfn LoPNeqn;knxLR;kf[kya fgre~AA X.64 AA
ikS’ks okfj ljkstkra ek?ks rUrq rMkxte~A
Qky~xqus dwilaHkwra pS=s pkSTT;a fgra ere~AA X.65 AA
Hkknzs dkSia Ik;% “kLrekf”ous pkSTT;eso pA
dkfrZds ekxZ”kh’ksZ p tyek=a iz”kL;rsAA X.67 AA
Meaning: “water belonging to ponds and tanks during the season gseUr (winter, i.e. November–
January) are good; during f”kf”kj (the cool season, i.e. January–March) also the same waters are
superior. During clUr (Spring, i.e., March–May) and xzh’e (summer, i.e. May-July) the water
belonging to wells, stepped deep wells and rocky springs are good. During clUr and xzh’e seasons
waters of rivers should not be used for drinking because during these seasons the river water
becomes contaminated with the leaves of poisonous trees etc. During rainy season aubhida water
(ground water of artesian character) or antariksha water (the atmospheric precipitation) are good.
During “kjn season, waters of the rivers and waters, illuminated by the sun during day time and
by the moon during nights, called amsudakam, are good. Ansudak water is destroyer of the
Tridosa, not causing abhisyanda and is free from bad qualities. It is equal to akasodakam, good
for brain, soft and cool. During “kjn season after the rise of star Agastya in the sky all waters
become pure. Vriddha Susruta said that during the month of Pusya waters from lakes or ponds,
during Magha waters from tanks, during Phalguna waters from wells, during Chaitra Chaunjya
(valley stream water), during Vaisakha Nairjhara water etc., during the months of Jyestha the
water of artesian character, Asadha the well water and in Kartika and Margasira all kinds of
waters are good”.
Factors affecting water quality
As seen from above shlokas of Bhava Prakash, we can identify some factors affecting the quality
of water. gse tye~ i.e. glacial water HkkSe tye~ i.e. ground water, uk<s; tye~ (river water), vkSnfHkn
tye~ (ground water flowing with artesian character), fu>Zj (water fall water), rMkx ty pond
Water), dkSi ty (wells water), pkSTT; ty (i.e. valley stream water, Shloka 65) aand their qualities
have been described in Bhava Prakasha in details, indicating the knowledge of the effect of
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geographic condition on the quality of water. These conditions are related to the differences in
the earth as vuwi] tkaxy and lk/kkj.k regions as described before in shlokas 26-27-28. The effect of
agricultural soil on water quality ¼dsnkj ty] Shloka 57) is also described. viz.
dsnkj% {ks=eqfnn’Va dSnkja rTtya Le`reA
dSnkja ok;;ZfHk’;fUn e/kqja xq: nks’kd`rAA X.57 AA
It also describes the effect of decaying vegetation on water quality. Also the effect of stagnation
and lack of the penetration of sun light in water, on the water quality have been discussed
(Shlokas 78 to 81). These verses show that the modern water quality related concepts were well
known during ancient times in India.
The knowledge of the hardness of water has been described in many shlokas (7,19,21,24,29 and
43) quoting the properties of various waters according to origin as:
/kkjuhja f=nks’k/uefunsZ”;dja y?kqA
lkSE;a jlk;ua cy~;a riZ.ka gykfn thoueAA X.7 AA
djdkta tya :{ka fo”kan xq: p fLFkje~A
nk:.ka “khrya lkUnza fiRrgRdQokrdr~AA X.19 AA
Here, lkSE;e~ (Saumayam) means soft and :{ka (ruksam) or nk:.ka (darunam) means hard water.
Diseases in relation to water have been described. This is clear from the verses X.27-31, X.78-
81 and some other verses. This discourse on water quality and related subjects is quite scientific
and shows broad outlook of ancient Indians.
Water Treatment
Shlokas 5 and 6 suggest collection of water in golden, silver, copper and glass vessels or earthen
pots, after filtrating from cloth. It reveals the attention paid to get clear water.
lkSo.ksZ jtrs rkezs LQfVds dkpfufeZrsA
Hkktus e`.e;s okfi LFkkfira /kkjxewP;rsAA X.6 AA
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In shloka 82, we are told that water treatment for drinking purpose should be done by heating or
boiling and filtration. Shloka 83 reveals the treatment of water with the aid of heated sand, stones
etc. and aromatic materials viz.
fufnra pkfi ikuh;a DofFkra lw;Zrkfire~A
lqo.kZ jtra yksga ik’kk.k fldrkefiAA X.82 AA
Hkz”ka lUrkI; fuokZI; lIr/kk lkf/kZra rFkkA
diZwjtkfr iqUukxikVykfnlqokflre~AA X.83 AA
“kqfp lkaUnziVL=fo {kq=tUrqfooftZre~A
LoPNa dudeqDrk?kS% “kq)a L;knnks’koftZreAA X.84 AA
i.kZewy folxzafFkeqDrkdud”kSoyS%A
xksesnsu p oL=s.k dq;kZancqizlknue~AA X.85 AA
Meaning: “contaminated water can be purified by boiling, by exposure to the sun’s ray or by
quenching with fire heated gold, silver, iron, stone or sand and flavouring it with the smell of
Camphor, jati (Chameli; Jasminum grandiflorum), Punnaga (Nogkesar; Calophyllum
inophllum), Patala (Padhar; cocsalpinia banducella) etc. and then filtration through clean cloth
makes water free from small germs. Purifying it with gold, pearl, etc. also makes it free from
pollution. Water should be made free from leaves, roots, stalks of lotus leaves, gold, pearls, cloth
etc.”
From above treatment procedure we gather that the positive effects of intense sunlight, heating,
filtration, aeration and addition of aromatic components are clearly revealed in the treatise. The
bad effects of stagnation of water, contamination of water by leaves, algae etc. are also described.
The treatment methods given need no costly inputs and no desirable qualities of water will be
changed, which is a measure drawback of the modern chemical methods of water treatment.
Wastewater Management Techniques
Lack of sanitation affects human development to the same or even greater extent as the lack of
clean water. While there may be an added stigma to discussing waste treatment, sanitation is
widely perceived as meriting a significant claim on financial and political resources as well on
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the evolution of mankind. According to Victor Hugo (1892), ‘The history of men is reflected in
the history of sewers’. This proverb adequately indicates about the importance of sanitation and
wastewater management.
The term sanitation is primarily used to characterize the safe/sound handling and disposal of
human excreta as well as other waste products (Avvannavar and Mani, 2008). It is well known
that the relationship between humans, water and sanitation has seen substantial changes, due to
the influence of cultural, social and religious factors throughout the ages (Sorcinelli, 1998;
Wolfe, 1999; De Feo and Napoli, 2007; Avvannavar and Mani, 2008; Lofrano and Brown, 2010).
However, all through the ages, wastewater has been considered filthy (Maneglier, 1994; Lofrano
and Brown, 2010). The process of evolution of wastewater management through the ages has
been discussed by several authors worldwide such as Tarr (1985), Maneglier (1994), Sorcinelli
(1998), Viale (2000), Sori (2001), and Neri Serneri (2007). More recently, Lofrano and Brown
(2010) have presented an in-depth review of wastewater management in the history of mankind.
In this review work they have categorically discussed about the evolution of sanitation through
different civilizations of the world, including the ancient Indus civilization.
It would be appropriate to mention Kenoyer (1997) about the new heights of the Indus
civilization, ‘that many of the technologies first developed in the Indus cities provided the
foundation for later technologies used in South Asia and other regions of the Old World’.
Wastewater management and sanitation were the major characteristics of the first urban sites of
the Harappan civilisation (Kenoyer, 1991). Adding to this, Lofrano and Brown (2010) found on
records that ‘the Indus civilization was the first to have proper wastewater treatment systems’ in
the ancient times. Sewage and drainage were composed of complex networks, especially in
Mohenjo-Daro and Harappa. Latrines, soak-pits, cesspools, pipes and channels were the main
elements of wastewater disposal. Figure 7.1 shows drainage and sanitation systems of Mohenjo-
Daro and Lothal cities of Indus valley civilization.
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Figure 7.1: Drainage and sanitation systems of Mohenjo-Daro and Lothal cities of Indus valley
civilization (after Khan, 2011; Kenoyer, 1998)
The houses were connected to drainage channels and wastewater was not permitted to flow
directly to the street sewers without first undergoing some treatment. First, wastewater was
passed through tapered terra-cotta pipes into a small sump. Solids settled and accumulated in the
sump, while the liquids overflowed into drainage channels in the street when the sump was about
75% full (Lofrano and Brown, 2010). The drainage channels could be covered by bricks and cut
stones, which probably were removed during maintenance and cleaning activities (Wolfe, 1999).
Further, cesspits were fitted at the junction of the several drains or where a drain was extended
for a long distance in order to avoid the clogging of the drainage systems (Wright, 2010). Fardin
et al. (2013) found that almost all the settlements of Mohenjo-Daro were connected to the drain
network.
In Jorwe, in present day Maharashtra, it has been demonstrated that the drainage system was
implemented from 1375–1050 BC (Kirk, 1975; Fardin et al., 2013). Later (around 500 BC),
Outlet of Great Bath
Sanitation/Drainage
Drain Outlet Terracotta Drainpipe
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Ujjain’s ‘drainage system included soak-pits built of pottery-ring or pierced pots’ (Kirk, 1975),
and it has been supposed that ring-wells were used for the disposal of wastewater (Mate, 1969).
In the 3rd century BC at Taxila, domestic wastewater was canalized out from the houses through
earthenware drain-pipes into soak-pits (Singh, 2008). During 1st century BC, drains were being
used for sewage disposal in Arikamedu, the southern part of India (Casal, 1949). Further, the
wastewater systems were improved around 150AD with the use of corbelled drains (Begley,
1983). Bhardwaj (1997) found that this system was draining water from basins supposed to be a
part of a textile and dye industry. This was the unique feature associated with this system as
compared to the rest of ancient India, where the wastewater disposal was implemented for
domestic effluents only.
Epilogue
From the above discussions it can be concluded that during the ancient times, modern concepts
of water quality, sanitation and waste water management technology were very well known to
the Indians and were in their advanced stages during the Indus valley civilization and later
periods. Water classification and viewing its quality in relation to environment satisfies the
modern concept of ecology. Water quality standards, factors affecting water quality, effect of
decaying materials on quality of water, lack of aeration in stagnating and deep water bodies etc.
were known which are in accordance to modern science. Water treatment methods using
filtration, pots of different materials like earthen, silver, gold etc., quenching with hot stones, sun
heating, aeration, addition of aromatic compounds etc. were adopted. These methods are
frequently used even now-a-days and are better than the chemical disinfectants as there is no
change in the desirable qualities and odours of water. Modern methods of wastewater disposal
systems based on centralized and decentralized concept as well as methods for wastewater
treatments during Indus valley civilization were even better than those used in the contemporary
world.
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As in many other parts of the world, civilization in India also flourished around rivers and deltas,
and rivers remain an enduring symbol of national culture. As has been mentioned earlier, the
Indus Valley civilization, one of the earliest civilizations, was the world's largest in extent, had
great and well planned cities with public and private baths, sewerage through underground drains
built with precisely laid bricks, and an efficient water management system with numerous
reservoirs and wells. Agriculture was practised on a wide scale, with extensive networks of
canals for irrigation. Irrigation systems, different types of wells, water storage systems and low
cost and sustainable water harvesting techniques were developed throughout the region at that
time (Nair, 2004). The Rig Veda clearly mentions about the life style, social structure, agriculture
and crops grown by the society at that time. Irrigation channels and kuccha and pucca wells are
also mentioned in different hymns (R.V. 19.4.2/RX2.9.4) (Bagchi and Bagchi, 1991).
Agriculture and livestock rearing occupied a prominent role during Jainism and Buddhism period
and channel irrigation was in vogue (Bagchi and Bagchi, 1991). McClellan III and Dorn (2006)
state that ‘the Mauryan empire was first and foremost a great hydraulic civilization’. This shows
the degree of knowledge about efficient utilization of water resources and their conservation for
the welfare of the society during that time.
During Mauryan period, raingauges were installed in different parts of the country to have areal
information of the rainfall and based on the information supplied, the 'Superintendent of
Agriculture' gave directions for sowing the seeds in different parts of the country (Srinivasan,
1975). Almost all ancient civilizations were confined to the areas of reliable water resources,
revealing the importance of water for development from very ancient days. During the time of
Rig Veda, we get many references to water use by means of rivers, wells, ponds etc. for
agriculture, domestic and other purposes. Verse I, 121.8 of Rig Veda reveals the same fact as:
v’Vk egksfno vknks gjh bg ?kqEuklkgefHk ;ks/kku mRle~A
gfja ;Rrs efUnua nq{kUo`/ks xksjHklefnzfHkokZrkI;e~AA R.V.I,121.8
Chapter-8
WATER RESOURCES UTILIZATION,
CONSERVATION AND MANAGEMENT
92
Similarly verses (I,23.18 and V, 32.2) state that the agriculture can be progressed by use of water
from wells, ponds etc. wisely and efficiently. The verse (VIII,3.10) of Rig Veda says about the
construction of artificial canals to irrigate desert areas also, which is possible only by efforts of
skilled persons (Ribhus/engineer) as:
;suk leqnzel`tks eghj;LrfnUnz o`f’.k rs “ko%A
l?k% lks vL; efgek u lUu”ks ;a {kks.kfjuqpØnsA R.V.VIII,3.10 AA
mruksa fnR;k b’k mr flU/kqjgfoZnkA
vi }kjs o o’kZFk%AA R.V.VIII,5.21 AA
Verses (VIII, 49.6; X64.9) speak about the importance of water for irrigation. The water from
wells, rivers, rain and from any other sources on the earth should be wisely used as it is a gift of
nature for well-being of all.
mnzho oftzUuorks u flTors {jUrhUnz /khr;%AA VIII,49.6 AA
ljLorh lj;q% flU/kq:feZfeeZ gks eghjolk ;Urq o{.kh%A
nsohjkiks ekrj% lwnf;RUoks ?k`roRi;ks e?kqeUuks vpZrAA X.,64.9 AA
Similar to Rig Veda, Yajur Veda also contains references, directing the man to use rain and river
water by means of wells, ponds, dams and distribute it to various places having need of water
for agriculture and other purposes as:
ue% L=qR;k; p iF;k; p ue% dkV~;k; p uhI;k; pA
ue% dqy~;k; p jjL;k; p ueks uns;k; p oS”kUrk; pAA Y.V.,16.37 AA
In the Atharva Veda, we have references to drought management through efficient use of
available water resources and water conservation. It clearly says that the water of river, well etc.,
if used efficiently, will reduce the intensity of drought, viz.
vkiks ;n~ oLriLrsu ra izfr rir ;ks Leku~ )sf’V ;a o;a f)’e%AA A.V.II,23.1
93
Verses VI, 100.2 and VII,11.1 of the Atharva Veda explains that the learned men bring water to
desert areas by means of well, pond, canals etc. (VI,100.2). It also stresses that the man should
think about the drought, flood and like natural calamities in advance and take preventive
measures accordingly as:
;n~ oks nsok vithdk vkflaTou /kUoU;qnde~A
rsu nso izlwrsuna naw’k;rk fo’ke~AA A.V.VI,100.2 AA
Verse XII,1.3 of the Atharva Veda explains that those who use rainwater wisely by means of
river, well, canals etc. for the purposes of navigation, recreation, agriculture etc., prosper all the
time as:
;LFkk leqnz mr flU/kqjkiks ;L;keRu d`’V;% laoHkwoq%
;L;kfena ftUofr izk’knstr lk uks Hkwfe% iwoZ is;sa n/kkrqAA A.V.XII,1.31 AA
“kar vkiks gseorh% “keq rs lUrq o’;kZ%A
“ka rs lfu’i{k vki% “keq rs lUrq o’;kZa%AA A.V.19.2.1 AA
Meaning: “That one should take proper managerial action to use and conserve the water from
mountains, wells, rivers and also rainwater for use in drinking, agriculture, industries etc.”
Similarly, one verse of the Atharva Veda (XX,77.8) directs the king to construct suitable canals
across mountains to provide water for his subject for agriculture, industry etc. and to facilitate
navigation between two areas as:
vkiks ;nfnz iq:gwr nnZjkfoHkqZOr ljek iwR;Z rsA
l uk usrk oktek nf’kZ Hkwfja xksek :tUufXMjksfHkxZ.kkuAA A.V.XX,77.8 AA
Water Resources Management
India has a fascinating and significant ancient tradition of conserving land and water and even
today, local people follow several such traditional conservation practices. As discussed in the
beginning of this chapter, out of the agricultural necessity, the science of water management was
given considerable importance during ancient India. During Mauryan era, the Pynes and Ahars
(the combined irrigation and water management system) in Magadh region were effective water
94
engineering tools. Ahars were reservoirs with embankments on three sides, built at the end of
drainage lines such as rivulets or artificial works like Pynes. Pynes were diversion channels led
off from the river for irrigation purposes and for impounding water in the Ahars. As a
representation, the Pyne-Ahar system is shown in Figure 8.1.
Figure 8.1: Ahar Pyne system in Gaya, South Bihar
(Image courtesy: Hindi Water Portal;https://www.thebetterindia.com/6963/tbi-videos-magadh-jal-
jamaat-helps-revive-2000-year-old-flood-water-harvesting-systems-in-gaya-bihar/)
Agricultural planning was common so as to manage the rainfall excess or deficit. It is very well
elaborated in Arthasastra as: “according to the rainfall (more or less) the superintendent of
agriculture shall sow the seeds which require either, more or less water”. Kautilya says that “king
should construct dams, reservoir etc. filled with water either perennial or drawn from some other
source or he may provide with sites, roads, timber and other necessary things to those who
construct reservoir of their own accords (Arthasastra, Tras. By Samsastry, Book II, Chapt. 1,
page. 46). He further says that the king shall exercise his right ownership ¼LokE;e½ with regard to
fishing, ferrying and trading of vegetables in Reservoirs or lakes ¼lsrq’kw½”.
During this period, embankments were constructed surrounding the fields to increase the water
holding capacity. Dams were constructed at strategic points with sluice gates to harness river
95
water with proper regulation facilities. Conduits were also constructed at that time to attain better
efficiency in irrigation (Bagchi and Bagchi, 1991). Figure 8.2 shows the Sudarsana lake,
Junagadh constructed during the reign of Chandragupta Maurya, by the provincial governor, the
Vaisya Pusyagupta; and subsequent improvements involving the addition of conduits during the
reign of Asoka, by his provincial governor, the Yavana king Tusaspha (Shaw and Sutcliffe, 2010;
Kielhorn 1905-6, p. 41).
Figure 8.2: A view of Sudarsana lake Girnar, Junagadh, Gujarat
(Source: https://junagadh.gujarat.gov.in/photo-gallery)
Recently, Sutcliffe and Shaw (2011) explored the Sanchi site (a well-known Buddhist site and a
UNESCO World Heritage site) in the Betwa river sub-basin (a tributary of Yamuna in Ganga
basin) in Madhya Pradesh. They found a number of dams equipped with spillways. They found
that these dams would have been built on the basis of a sound knowledge of the principles of
water balance. In addition to the design of the reservoirs, the presence of spillways on at least
two of the larger dams, which would pass floods of about 50 years’ return period, suggests that
flood protection was also taken into account. The Arthashastra of Kautilya also gives us an
extensive account of dams and bunds that were built for irrigation during the period of the
Mauryan Empire. The water supply systems were well managed within the framework of strict
rules and regulations. Specifically, an organized water pricing system, which is an important part
of water management, was also developed during this period as evidenced by following lines of
96
Arthasastra: “those who cultivate irrigating by manual labour ¼gLrkizofrZeke~½ shall pay 1/5 the
produce as water rate ¼mndkHkkxe½( by carrying water on shoulders ¼LdU/kkizkofrZeke~½ = (water lift
worked by bullocks), 1/4th of the produce; by water lifts ¼L=ksrks;a=kizofrZeke~½ 1/3rd of the produce;
and by raising water from rivers, lakes, tanks and wells ¼ufnljklrrdkdqinkgkVe~½ 1/3rd or 1/4th of
the produce (Arthasastra, Tras. By Samasastry, Book II, Chapt. XXIV page 131)”.
In Vrhat Samhita, we get a few references regarding the orientation of ponds so as to store and
conserve water efficiently, plantation types for bank protection and proper sluicing to protect
reservoir from any possible damage as:
ikyh izkxikjk;rkEcq lqfpja /kRrs u ;kE;ksRrjk
dy~yksyS[knkjesfr e:rk lk izk;”k% izsfjrS%A
rka psfnPNfr lkjnk:fHkjika lEikrekokj;sr
ik’kk.kfnHkjso ok izfrp;a {kq..ka f}ik”okfnfHk%AA Vr. S. 54.118 AA
Meaning: a pond laid east to west retains water for a long time while one from north to south is
spoilt invariably by the waves raised by the winds. To render it stable, the walls have to be lined
with timber or with stone or the like and the adjoining soil strengthened by stamping and
trampling of elephants, horses etc.
ddqHkoVkezIy{dnEcS% lfupqytEcwosrluhiS%A
d qjcdrkyk”kksde/kwdScZdqyfofeJS”pko`rrhjkeAA Vr.S.54.119 AA
Meaning: the banks must be shaded by Kakubha Vata,Amra, Plasa, Kadamba, Nicula, Jambu,
Vetasa, Nipa, Kuravaka, Tala, Asoka, Madhuka and Bakula trees.
In next verse (Vr.S.54.120), it directs the construction of spillway as:
}kja p uSokZfgdesdns”ks dk;Z f”kykflTprokfjekxZe~A
dks”kkfLFkra fufoZoja dikVa d`Rok rr% ika”kqfHkjkoisRre~AA Vr.S.54.120 AA
Meaning: an outlet for the water has to be made on a side with the passage being laid with stones.
A panel without apertures has to be fixed in a frame, which is fastened to the earth with mud and
clay.
97
From this discourse, we can realize that the water management was getting due importance in
ancient India and even bank protection, spillway etc. and other minor aspects were given due
consideration.
In ancient India much attention was also paid to the proper location of artificial tanks. Various
techniques were applied and equally different materials were utilized for the construction of
works. It appears that special works for treatise on science of hydrology must have existed in
south India. The Porumamilla tank inscription of Bhaskara Bhavadura dated A.D. 1369 throws
an abundant light on the elaborate method of construction of tanks and dams in the south India.
Constituents of a good tank are well described in ancient literature. According to the Sastra
(Epigraphia Indica, Vol, PP. 108, Quotes from Hemadri, Verses 37-38, Srinivasan T.M., 1970),
the following are the 12 essentials of a good tank as: (i) A king endowed with righteousness,
rich, happy and desirous of the permanent wealth and fame; (ii) Brahmana learned in hydrology
(Pathas-Sastra); (iii) Ground adorned with hard clay; (iv) A river conveying sweet water (and)
three Yojanas distance from its source; (v) The hill, parts of which are in contact with tank; (vi)
Between (these portions of the hill) a dam (built) of a compact-stone wall, not too long but firm;
(vii) Two extremes (Srimga) pointing away from fruit (giving) land (Phala-Sthira) outside; (viii)
The bed, extensive and deep; (ix) A quarry containing straight and long stones; (x) The
neighbouring fields, rich in fruit and level; (xi) A water course (i.e., the sluice) having strong
eddies on account of the portion of the mountain (adri-sthana); and (xii) A gang of men (skilled
in the art of its construction). With these 12 essentials, an excellent tank is easily attainable on
this earth.
From these points on comparison with the modern, science of water management regarding
construction of dams and reservoirs, we will find that the technique in those days was just
comparable to the modern sophisticated engineering, as far as general requirements are
concerned. Along with these 12 essentials, six faults were also recognized which will reduce the
usefulness of the reservoir and water conservation will become difficult. These faults (Dosas)
are as follows (Epigraphia Indica, Vol. XIV,PP.108, Quotes from Hemadri, Verse 39, through
Srinivasan T.M. (1970) as:
(i) Water oozing from the dam
(ii) Saline soil
98
(iii) Situation at the boundary of two kingdoms
(iv) Elevation (Kurma) in middle (of the tank) bed
(v) Scanty supply of water and extensive stretch of land (to be irrigated), and
(vi) Scanty ground and excess of water
Epilogue
The above discussion brings out that water use by means of wells, ponds, tanks and canals was
prevalent during the ancient times, along with the efforts to supply water in deserts also.
Organized water pricing system was prevalent and preventive measures against natural
calamities such as floods, drought etc. was common. Construction methods and materials of dam
and ponds, essential site and other requirements of good tanks, bank protection spillways etc.
were paid sufficient attention. High level of development was achieved in the areas of proper
location and orientation of tanks, lining of banks, evapotranspiration control, drought
management, etc. Thus, ancient India was at a high plane of development in the field of
engineering in irrigation and water conservation. State-of-the-art irrigational facilities were
established during the ancient times in India for increasing agricultural produce apart from
improved drinking water supplies for the people. Ancient India was highly progressive in the
area of water management. Such remarkable development in the absence of scientific
instruments of the ancient times invokes astonishment and admiration of the readers.
99
Water is most precious and critical natural resource for survival of all the living beings. It
hasbeen so intimately linked to our very existence and societal and cultural developments that
ithas become the source of rich symbolism, traditions, rituals and religious beliefs. Water played
a pivotal role in shaping the life and living standards of the people of the great civilizations of
the world. Throughouthistory, our vital relationships to water have led to material testimonials
of how waterwas used, managed and valued. The first successful efforts to control the flow of
water were mainly driven by agricultural needs for irrigation purposes. With a more detailed
understanding of the hydrologic cycle, nature of surface water, ground water and rain water;
robust and sustainable water management systems were also evolved in all the civilizations that
prospered for thousands of years.
Besides the spiritual growth, ancient India also exhibited the growth of science. The Indus Valley
Civilization, one of the earliest and most developed civilizations, was the world's largest in extent
and epitomises the level of development of science and societies in proto-historic Indian sub-
continent. As rightly observed by Jansen (1989), the Indus people were known for their obsession
with water. They prayed to the rivers everyday and gave them a divine status. Ancient Indian
literature, dating back from the age of the Vedas, further witnesses this development of sciences
(including the water science). Numerous references exist in Vedic literature, Arthashastra,
Puranic sources, VrhatSamhita, Mayuracitraka, Meghmala, Jain, Buddhist and other ancient
Indian literature which illustrate the status of the knowledge of hydrology and water resources
in ancient India.
As we investigate deeper into hydrologic references in Indian mythology, many fascinating
dimensions of the early scientific endeavours of mankind emerge. Fortunately, the ancient Indian
works have been well documented and provide us with pointers to the human history in general,
and growth of water sciences in India in particular. Number of research works related to water
science developments in ancient India have been also published by national and international
research community. While updating this book, an attempt has been made to incorporate a
number of recent national as well as international research papers and technical book published
by various national and international institutions. Figures illustrating various concepts,
Chapter-9
CONCLUDING REMARKS
100
hydrological processes and water engineering techniques have also been included to clarify the
concepts and help forming clear mental image of the developments.
What is less known, however, is the rigorous discussion in the Vedic literature and other ancient
Indian literature on several aspects of hydrologic processes and water resources development
and management practices as we understand them today. It is high time that we realize and
question our current systems of water resources utilization and management and acknowledge
our traditional wisdom and practices and apply them to the modern context. Hence, a comparison
of hydro-technologies in ancient times to that of the modern times is required. Although to some
extent, there are differences in the tools and techniques used today and the scale of applications,
still there are no differences in the fundamental principles used. Even the lifestyle related to the
hygienic standards of a civilization may not be a recent development. For example, flushing
toilets equipped with seats resembling present-day toilets and drained by sewers has existed
during ancient times.
Finally, in view of our immense traditional knowledge in water science and technology, it is
important and helpful to study and represent the connection between water and humans more
deeply as was prevalent in India during ancient times.
101
A: Primary Sources:
1. Rig Veda Samhita (3000 B.C.), (i) Bhasya by Maharshi Dayananda Saraswati (Hindi),
Published by Dayananda Sansthan, New Delhi-5.
(ii) Bhasye by Swami Satyaprakash Saraswati (English), Pub-lished by Veda Pratisthan,
New Delhi.
2. Sam Veda (3000 B.C.) Bhasya by Swami Dayananda Saraswati, Published by Dayananda
Sansthan, New Delhi-5.
3. Yajur Veda (later than Rig Veda), Bhasya by Swami Dayananda Saraswati, (Hindi)
Dayananda Sansthan, New Delhi-5.
4. Black Yajur Veda (Taithiriya Sanhita) (Later than Rig Veda), Edited by Pt. Shripad
Damodar Satvalekar, Swayadhya Mandal, Maradi, Disit. Balsod, Gujara.
5. White Yajur Veda (Vajasaney Sanhita) (Later than Rig Veda, English Trans. By R.T.H.
Griffith, Munsiram Manohar lal Publishers, Rani Jhansi Road, New Delhi, 1987.
6. Atharva Veda (the latest Veda), Bhasya by Pt. Khem Karan Das Trivedi, Sarvadeshik
Arya Pratinidhi Sabha, Maharshi Dayananda Bhavan, Ramlila Maidan, New Delhi.
7. Satapatha Brahmana (2000 B.C.), Edited by Pt. Ganga Prasad Upadhyaya. The Research
Institute of Ancient Sanskrit Studies, New Delhi-8.
8. Gopatha Brahmana (much later than 1000 B.C.), Bhasya by Pt. Khem Karan Das Trivedi,
Edited by Dr. Prajna Devi and Medha Devi, Published by Atharvaveda office, 34,
Lukarganja, Allahabad, 1977.
Epics:
9. The Vaimiki Ramayana (800 B.C. to 200 B.C.), Gita Press, Gorakhpur, in two volumes
with Hindi translation.
10. The Mahabharata (400 B.C. to 400 A.D.) Translated by Pt. Ramanarayana Datta Shastri,
Pandeya ‘Ram” Gita Press, Gorakhpur in six volumes.
Smriti:
11. Manusmriti (200 B.C. or earlier than that), Edited by Pt. Haragovinda Shastri,
Chowkhamba Sanskrit Series Office, Varanasi -221 001, 1984.
Philosophica System:
12. Vaisesika Sutra of Kanada (Pre-Buddhist, 600-700 B.C.), Translated by A.E. Gough,
Oriented Books Reprint Corporation. 54, Rani Jnahsi Road, New Delhi-110 055, 1975.
Grammer:
13. Panini’s Astadhayayi (700 B.C.), Bhasya by Brahmadatta Jijnasu, published by Ramlal
Kapoor Trust, Nahalagarh, Sonipat, Haryana, 1985 two volumes.
Polity:
14. Arthasastra (Kautilya, 400 B.C.), Ed by R. Shamashastri, Eng. Trans: Ibid. Mysore
printing and publishing House, Mysore, 1967.
Puranas (6th century B.C. to 700 A.D.):
15. Brahmanda purana (3rd, 4th century A.D.) Edited by Dr. Chamana Lal Goutam, Published
by Sanskrit Sansthan Ved Nagar, Bareilly-243 003, two volumes, 1988.
BIBLIOGRAPHY
102
16. Garuda Purana, published by Tejkumar Book Depot Pvt. Ltd. Lucknow-26001, 1989.
17. Kurma Purana, Edited by Pt. Shri Ram Sharma, Sanskrit Sansthan, Ved Nagar, Bareilly,
two volumes, 1986.
18. Linga Purana, Ibid. 1987.
19. Markandeya Purana, Hindi Trans. By Dr. Dharmendranath Shastri, Sahitya Bhanda,
Subhash Bazar, Meerut-250 002, First Edition, 1983.
20. Matsya Purana (6th century B.C. to 4th century A.D.), Edited by Pt. Shri Ram Sharma,
Veda Nagar, Breilly (UP), two volumes, 1989.
21. Narada Purana, Ibid., 1984.
22. Padma Purana, Ibid., 1986.
23. Skanda Purana, (7th century A.D.), Ibid. 1988.
24. Vayu Purana, Hindi Trans. By Rama Pratap Tripathi Sastri, Hindi Sahitya Sammelan
Prayag, 12, Sammelan Marg., Allahabad, 1987.
25. Visnu Purana: Same as 24th above, 1989.
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26. Vrhat Sanhita (550 A.D.) by Varahamihira, Edited and Bhasya by Pt. Achyntanada Jha,
Chow Khamba Vidyabhawan, Varanasi=221 001 1988.
27. Mayurcitraka (Nardiya), Manuscript No. 34332, Kept at Saraswati Bhavan Library of
Sampurnananda Sanskrit University, Varanasi.
28. Meghamala (around 900 A.D.), Manuscript No. 37202, Kept at the Saraswati Bhavan
Library of above University.
Others:
29. Meghadutam of Kalidas (100 B.C.), Bhasya by Malinath, Edited by Dr. Jaya Shankar
Tripathi, devabhasa Prakashan, Allahabad-6.
30. Kalidas Granthavall: Edited by Sitaram Chaturvedi, Chowkhamba Prakashan, Varanasi,
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Albedo: The portion of the total incoming radiation that is reflected back to space
expressed as a ratio of the reflected to incoming radiation.
Alkalinity: A term used to represent the content of carbonates, biocarbonates,
hydroxides and occasionally borates, silicates and phosphates in water
expressed in ppm (part per million) or mg/lit of equivalent calcium
carbonate.
Arid Zone: Region or climate lacking sufficient moisture for crop production without
irrigation; upper annual limit of precipitation for cool region is 25 cm and
for tropical region is 40-50 cm.
Artesian well: A well penetrating an artesian aquifer. An artesian aquifer is overlain and
underlain by a confining layer so that water in these aquifers occurs under
pressure. Boring in this aquifer causes the water to rise due to its own
pressure.
Atmosphere: The word atmosphere is taken to refer to the gaseous envelop of any
heavenly body, and especially that of the earth.
Boulder: Largest unit in sedimentary rocks. Soils etc. usually bigger than 10 cm in
size.
Canal: Artificial water course used for irrigation or inland navigation.
Capillarity: The rise of soil water by adhesion and surface Tension forces as a
continous film around soil particles and in the capillary spaces.
Caverns: Synonymous with cave, though sometimes it implies a cave of large
dimensions. A cave is the under ground hollow space in the earth’s crust
which may be entered from the surface.
Climatology: It is a subdivision of meteorology which deals with the average or normal
or collective state of the atmosphere over a given area within a specified
period of time i.e. it studies the sum (total) of all atomospheric infiuences.
Principally temperature, moisture, wind, pressure and evaporation.
Cloud: A mass of small water drops or ice crystais formed in the atmosphere due
to condensation of water vapour at great height above the land.
Condensation: The physical process of transformation from the vapour to the liqid state.
Convection: A process of heat transfer within the atmosphere (or within a gas or fluid),
which involves the movement of the medium itself.
Dales: Open river valleys.
Delta: Roughly triangular area of river-transported sediment at the river mouth
deposited by decreasing velocity of water. The sediment is constituted
mainly of sand, clay, remains of brackish water organisms, debris of
plants and animals washed from land. Delta is formed on low lying
coastlines.
Desert: Almost barren land having arid hot or cool climate, resulting in sparse
vegetation. A desert may have a poor grass-land or scrub.
GLOSSARY OF TERMS
108
Drought: Lack of rainfall so great and long continued as to affect injuriously the
plant and animal life of a place and to deplete water supplies both for
domestic purposes and for the operation of power plants. Especially in
those regions where rainfall is generally sufficient for such purposes. The
term has different cannotations in various parts of world e.g. In bali a
period of 6 days without rain is drought. In USA a drought is defined as a
period of 21 days or more when the rainfall is 30% or less of the average
for the time and place. In parts of Libya, droughts are recognized only
after two years without rain.
Ecology: Science which deals with interrelations of organisms and their
environment.
Environment: Sum total of all external conditions influencing the existence or
development of an organism or a community.
Erosion: Wearing away of land surfaces or detachment and movement of soil, rock
etc. by flowing water, wind, ice, gravity etc.
Evaporation: The process by which the water is changed from the liquid state to a
gaseous state below the boiling point through the transfer of heat energy.
Evapotranspiration: Combined loss of moisture from soil by evaporation and from
vegetation by transpiration from a given area in a specified time period.
Flood: The flow of water which causes submergence of land not usually covered
with water, or an increase in the depth of water on land already partially
submerged, through a temporary rise in river lake or sea levels.
Flood Plain: The low–lying land that bordrs a river and is subjected to periodic
flooding. It is camposed of deposits of sediment (alluvium) of variable
thickness laid down by the flood waters above the rock floor and is
bounded by low bluffs.
Fog: Droplets of water suspended in the lower layers of the atmosphere
resulting from the condensation of water vapour around nuclei of floating
dust or smoke particles. A visibility of less than 1 Km is the internationally
recognized definition of fog.
Frigid Zone: A general term for Arctic- Antarctic type climates or for areas where the
surface is snow covered for a large part of the year and where the sub soil
is permanently frozen.
Frost: A weather condition that occurs when the air temperature is at or below
00C. Moisture on the surface of the ground and objects freezes to form an
icy deposit.
Geomorphology: The study and interpretation of the origins and development of land
forms on the earth’s surface.
Glacier: A mass of ice that moves under the influence of gravity along a confined
course away from its source area. It is formed by the accumulation and
compaction of snow. which is transformed to firn and ultimately to
glacier ice.
109
Gravel: A deposit of unconsolidated material ranging in size from 2 to 60 mm.
The particles are usually water worn and hence rounded, and are derived
from more than one type of rock.
Ground Water: Water that is contained in the soil and underlying rock. Ground Water
may be derived from rain water that has percolated down or from water
that was trapped within the rock during its formation.
Humidity: The amount of water vapour present in the atmosphere.
Hurricane: A wind that has a velocity in excess of 32.7 m per second. It is tropical
cyclone occurring around the Caribbean Sea and Gulf of Mexico.
Hydrologic Cycle: The cyclic movement of water between the atmosphere, the land and
the sea. Water is released into the atmosphere as water vapour through
evapotranspiration. After condensation within the atmosphere to form
clouds it returnes to the land and to its water bodies as precipitation. This
water may runoff the land in rivers streams into lakes and the oceans or
move under ground as ground water. Water keeps on moving
continuously among above facets of hydrological cycle.
Hydrology: The study of water on the earth. Including its chemical and physical
properties, ocourrence, distribution, and circulation on the surface and
below the ground surface.
Infiltration: The seepage of water into the soil. The maximum rate at which rainfall
can be absorbed by a soil in a given condition is known as infiltration
capacity.
Insolation: The radiant energy that reaches the surface of the earth from the sun.
Interception: The capture of drops of rain by the leaves, branches, and stems of plants.
The interception of the rainfall by the vegetation cover prevents some of
its from reaching the ground.
Ionosphere: The part of earth’s atmosphere extending upwards above the stratopause
from an altitude of about 60 km.
Meander: A pronounced curve or loop in the course of a river channel.
Meteorology: The scientific study of the atmosphere and the physical processes at work
within it including pressure wind, temperature, clouds, pressure etc.
Mist: A reduction of visibility within the lower atmosphere to 1-12 km caused
by condensation producing water droplets within i.e lower layers of the
atmosphere.
Monsoon: A large-scale seasonal reversal of winds pressure and rainfall in the
tropics. The largest and best developed monsoonal area in the world is
South East-Asia.
Perennial river: Rivers flowing throughout the year are called perennial rivers.
Pervious Strata: A rock system through which water can pass freely as a result of joints,
bedding planes, cracks and fissures in the rock.
Physiography: The study of the surface forms of a region. The word has changed its
meaning over the years from covering the whole of physical geography
including geomorphology.
110
Plateous: An extensive elevated area of relatively flat land. Widespread movements
of the earth’s crust may result in vertical warping, which produces
plateaus and rift valleys divided by faults.
Pore space: The amount of space between the mineral grains of rock, soil or sediment.
Precipitation: The particles of water or ice that form within clouds and fall towards the
earth’s surface.
Rain gauge: An instrument designed to measure rainfall. In its simplest form it consists
of a funnel fitted into acollecting vessel. Any rain collected in the vessel
over a set period of time is measured in a specially graduated measuring
cylinder, an exercise that occurs twice daily at most meteorological
stations.
Rain Shadow: An area of low rainfall in the lee of hills or mountain ranges.
Reservoir: A storage area for water usually a river valley that has been dammed to
retain water for one or more purposes, such as irrigation, industrial use,
water supply, hydro-electric power or recreation.
Rills: Erosion of the soil surface by shallow short-lived channels. These small
channels are called rills.
Saline soil: A group of intra zonal soils that contain high concentrations of salts such
as common salt. They often occur in semiarid and arid areas where here
is strong evaporation.
Semi Arid: The climate of the areas between desert and tropical grassland. The mean
annual rainfall ranges between 100 mm to 300 mm.
Sluice: Channel or conduit to drain off surplus water at high velocity or for
passing debris. Also, to allow a water flow at high velocity for ejecting
debris.
Snow: A form of precipitation consisting of crystals of ice. It is produced when
condenstation takes place at a temperature below freezing point.
Spillway: An open or closed passage cut in soil or rock. When a dam is full, any
further incoming water flows over or through the spillway without any
damage to the structure.
Stratosphere: The layer of the atmosphere that lies between the tropopause, at an
average altitude of about 8 km, and the stratopause, at about 50 km.
Temperate Region: The division of the world based on temperature lying between the
torrid and frigid zones, and meaning an area where there are no extremes
of temperature.
Termite mound: The nest made from mud or plant debris, that, houses a colony of
termites (Tropical type of ant),
Topography: The surface features (i.e. land forms) of an area of land or sea bed.
Tornado: A violently rotating storm in which winds whirl around a small area of
extremely low pressure.
Torrid: One of the three divisions of the world based on temperature. It is the zone
lying between the tropics.
Troposphere: The lowest layer of the earth'satmosphere.
Turbudity: The muddiness of water resulting from suspended sediment.
111
Turbulence: An irregular disturbed flow of fluid e.g. water, air).
Water falls: A steep cliff like section of a river channel down which water falls
vertically.
Water lift: Any mechanism (generally lever principle) to raise the water from a
source of lower datum to obtain water for useful purposes.
Water oozing: Water seeping out of the ground and wetting it without perceptible flow.
Water Table: The upper surface of the zone of saturated rocks i.e. rocks in which all
voids are filled with water.
Water Treatment: Any method used to obtain potable water from a contaminated source
of water.
Water uptake: Water ascends upward through the capillarity of soil and root system of
plants. The utilization of water by plants is termed as water uptake.
Water Veins: The underground structures throughwhich the water moves through the
soil. These are passages formed by the interconnections of pore spaces of
soil. In ancient Indian literature these have been said to be resembling the
veins in the human body.
112
STUDY TEAM FOR FIRST EDITION
Satish Chandra : Director
T. M. Tripathi : Scientist-B
V. K. Srivastava : Documentation staff
EDITORS OF SECOND EDITION
Sharad Kumar Jain : Director
A. K. Lohani : Scientist-G
S. D. Khobragade : Scientist-F
P. K. Singh : Scientist-D
Md. Furqan Ullah : A. L. I. O.
Charu Pandey : L. I. A.